Touch-sensitive sheet member, input device and electronic apparatus

ABSTRACT

A touch-sensitive sheet member contains a body having predetermined hardness and a sheet shape and a sense-of-touch-representing unit that represents a sense of touch. The sense-of-touch-representing unit has a predetermined size and is arranged at positions of the body or at a predetermined position of the body. The touch-sensitive sheet member also contains a medium-supplying unit that supplies medium to the sense-of-touch-representing unit.

CROSS REFERENCE TO RELATED APPLICATION

The present application is a continuation application of U.S. patentapplication Ser. No. 12/340,063, filed Dec. 19, 2008, which applicationclaims priority to Japanese Patent Application JP 2007-330715 filed inthe Japanese Patent Office on Dec. 21, 2007, the entire contents ofwhich is being incorporated herein by reference.

BACKGROUND

In resent years, a user (the operator) has often used a digital cameraequipped with various kinds of operation modes to shoot a subject andhas often taken various kinds of contents in a mobile phone or aninformation mobile terminal such as a Personal Digital Assistants (PDA)to utilize them. The digital camera, mobile terminal device and the likehave their input devices. An input unit such as a key board and a JOGdial, a touch panel formed by combining a display unit, and the like hasbeen often used for the input device. Further, an input device in whichdisplay contents are changed over when the user's finger slides on adisplay screen has developed.

Japanese Patent Application Publication No. H02-230310 has disclosed onpage 2 and FIG. 1 thereof a menu selection device relating to a functionof the above-mentioned input device. This menu selection device has anitem selection means and an item input means. The item input means isprovided on the item selection means, selection and input of the itemare assigned to the same key, and an item display key and an itemselection and input key are provided in parallel.

Japanese Patent Application Publication No. 2005-063227 has disclosed onpage 8 and FIG. 15 thereof another input device. This input device has awindow aperture that is provided at a predetermined position of acasing. The item selection is executed by sliding an operation buttonexposed from this window aperture. A predetermined region in a specifieditem election screen is expanded and displayed by pressing the otheroperation knob.

Japanese Patent Application Publication No. 2004-070505 has disclosed onpage 5 and FIG. 3 thereof an input device accompanied with vibration,which is mountable on an electronic apparatus such as anair-conditioner, an audio or the like. This input device is providedwith an operation member that is used concurrently as functions of arotary switch, a push switch and a slide switch. Selection of theoperation item or the input determination operation is executed byrotating, sliding or pushing down the operation member and any vibrationis accompanied at a time of the input determination operation.

An input device combined with an actuator has been also developed. Theactuator is made by bonding piezoelectric devices having two layers ormore which have different distortion amounts or by bonding apiezoelectric device and a non-piezoelectric device. When a vibrationcontrol voltage is applied to the bonded piezoelectric devices and thelike, the actuator dynamically utilizes bending deformation of thebonded piezoelectric devices and the like, which occurs based on anydifference in the distortion amounts between them (vibration bodyfunction thereof).

Japanese Patent Application Publication No. 2004-094389 has disclosed onpage 9 and FIG. 4 thereof an input-output device and an electronicapparatus, which are provided with such a piezoelectric actuator. Thiselectronic apparatus is provided with an input-output device including amulti-layer piezoelectric actuator of bi-morph type and a touch panel,and this piezoelectric actuator feeds back different senses of touchcorresponding to kinds of information through the touch panel to theuser. The input-output device has a piezoelectric-member-supportingstructure in which a piezoelectric actuator is mounted on the supportframe through a support portion. The support portion is bonded on acenter upper portion of the piezoelectric actuator and/or this supportportion is attached to the touch panel. Supplying a vibration controlvoltage to the piezoelectric actuator allows a vibration to betransmitted to the touch panel.

The electronic apparatuses disclosed in Japanese Patent ApplicationPublication No. H02-230310 mounts an input device with the touch inputfunction in which the touch panel and the display unit are combined, butwhen an icon is selected on the display unit, the sense of touchsynchronized with the selection thereof is not given to the operator.

Also, the input devices disclosed in Japanese Patent ApplicationPublications Nos. 2005-063227 and 2004-070505 give a key operationfeeling to an operator based on a sense of touch that a finger of theoperator feels when a dome-shaped switch is pushed down. However, thesense of touch that the finger of the operator feels is given by only auniform vibration or a force change mainly within a contact surface ofthe finger and an input surface.

The input device disclosed in Japanese Patent Application PublicationNo. 2004-094389 introduces a plurality of piezoelectric actuators withrespect to improvement of input operability using the touch-sensitivedevice to reinforce the representation based on the sense of touch.However, an effective contact area of an operator's finger and an inputsurface for receiving vibration is small with respect to a size (outsideone) of each of the piezoelectric actuators. It is difficult torepresent a great variety of force changes in the input surface thereof.

It is desirable to provide a touch-sensitive sheet member, an inputdevice and an electronic apparatus in which concave shapes or convexshapes for representing sense of touch are built at predeterminedpositions by devising a structure and a function of an touch sheetmember and by which it is possible to improve operability in the touchsheet or compatibility in the nonskid sheet.

SUMMARY

The present application relates to a touch-sensitive sheet member and aninput device using the same, which are applicable to an electronicapparatus such as a digital camera, a video camera, a mobile phone, amobile terminal device, a desk-top type personal computer (hereinafterreferred to as PC), a note type PC, and a braille block apparatusincluding a touch-sensitive input function for presenting a sense oftouch when touching an icon screen with an operator's finger or thelike.

According to an embodiment, there is provided a touch-sensitive sheetmember including a body having predetermined hardness and a sheet shapeand a sense-of-touch-representing unit that represents a sense of touch.The sense-of-touch-representing unit has a predetermined size and isarranged at positions of the body or at a predetermined position of thebody. The touch-sensitive sheet member also includes a medium-supplyingunit that supplies medium to the sense-of-touch-representing unit.

According to the embodiment of the touch-sensitive sheet member, themedium-supplying unit supplies the medium to thesense-of-touch-representing unit that represents the sense of touch,which has a predetermined size and is arranged at positions of the bodyor at a predetermined position of the body. For example, theair-circulating unit constituting the medium-supplying unit sends air tothe aperture of the body or takes in air from the aperture of the body.

Consequently, the sense-of-touch-representing unit comes to give theconcave and convex feeling to the operation body by air blown out of theaperture and by air flowed into the aperture at positions of the body orat a predetermined position of the body. In this manner, even if themember surface is observed to be a flat shape, when the member surfaceis touched actually with a hand or a finger and a slide is executed fromthe body to the sense-of-touch-representing unit, it is possible torepresent the sense of touch which gives the concave and convex touchfeeling to the operation body at positions of the body or at apredetermined position of the body. Thus, the embodiment of thetouch-sensitive sheet member may be applied to a programmable nonskidsheet at a grip portion of various kinds of electronic apparatushousings or the programmable touch-sensitive input sheet or the like foricon touch in the input device.

According to another embodiment, there is provided an input device thatinputs information by any one of a slide operation and a press operationof an operation body. The input device contains a display unit having anoperation surface, a detection unit that detects any one of a slideposition and a press position of the operation body, the detection unitbeing provided at the display unit having the operation surface, and atransparent touch-sensitive sheet member on which any one of slideoperation along the operation surface of the display unit and the pressoperation to the operation surface of the display unit is executed, thetouch-sensitive sheet member covering at least a portion of thedetection unit. This touch-sensitive sheet member includes a body havingpredetermined hardness and a sheet shape, a sense-of-touch-representingunit that represents a sense of touch, the sense-of-touch-representingunit having a predetermined size and being arranged at positions of thebody or at a predetermined position of the body, and a medium-supplyingunit that supplies medium to the sense-of-touch-representing unit.

The embodiment of the input device is provided with the embodiment ofthe touch-sensitive sheet member. Even if the display surface isobserved to be a flat shape, when the icon image or the like displayedon the display unit is touched with a hand or a finger and a slide isexecuted from the body to the sense-of-touch-representing unit, it ispossible to represent the input operation accompanied with the concaveand convex feeling. This enables the input device with the programmabletouch-sensitive input sheet for icon touch to be provided.

According to a further embodiment, there is provided an electronicapparatus containing a housing and an input device that inputsinformation by any one of a slide operation and a press operation of anoperation body. The input device is provided at the housing. The inputdevice contains a display unit having an operation surface, a detectionunit that detects any one of a slide position and a press position ofthe operation body, the detection unit being provided at the displayunit, and a transparent touch-sensitive sheet member on which any one ofslide operation along the operation surface of the display unit and thepress operation to the operation surface of the display unit isexecuted, the touch-sensitive sheet member covering at least a portionof the detection unit. The touch-sensitive sheet member includes a bodyhaving predetermined hardness and a sheet shape, asense-of-touch-representing unit that represents a sense of touch, thesense-of-touch-representing unit having a predetermined size and beingarranged at positions of the body or at a predetermined position of thebody, and a medium-supplying unit that supplies medium to thesense-of-touch-representing unit.

The embodiment of the electronic apparatus is provided with theembodiment of the input device, so that it is possible to provide theelectronic apparatus with the programmable touch-sensitive input sheetfor icon touch linked with the display contents.

Moreover, it is possible to improve miniaturization and operability ofthe input device, thereby enabling the reductions of the miss-operation,the cost down and the simplification of the manufacturing process of theelectronic apparatus to be realized.

Additional features and advantages are described herein, and will beapparent from the following Detailed Description and the figures.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a perspective view of a touch-sensitive sheet member 100 as afirst embodiment for showing a configuration thereof;

FIGS. 2A and 2B are plan and front views of the touch-sensitive sheetmember 100 including partial cross-sections for showing an air supplyexample in the touch-sensitive sheet member 100;

FIG. 3 is a cross-sectional view of a blower 3 b showing a configurationthereof;

FIG. 4 is an exploded perspective view of the touch-sensitive sheetmember 100 showing an assembly of a base member 1 and a flow channelpanel 2 in the touch-sensitive sheet member 100;

FIG. 5A is a plan view of a flow-out port and FIG. 5B is across-sectional view thereof taken along an arrow of X1-X1 shown in FIG.5A;

FIG. 6A is a plan view of a flow-out port showing a modification example(No. 1) thereof and FIG. 6B is a cross-sectional view thereof takenalong an arrow of X2-X2 shown in FIG. 6A;

FIG. 7A is a plan view of a flow-out port showing a modification example(No. 2) thereof and FIG. 7B is a cross-sectional view thereof takenalong an arrow of X3-X3 shown in FIG. 7A;

FIG. 8A is a plan view of a flow-out port showing a modification example(No. 3) thereof and FIG. 8B is a cross-sectional view thereof takenalong an arrow of X4-X4 shown in FIG. 8A;

FIG. 9A is a plan view of a flow-out port showing a modification example(No. 4) thereof and FIG. 9B is a cross-sectional view thereof takenalong an arrow of X5-X5 shown in FIG. 9A;

FIG. 10A is a plan view of a flow-out port showing a modificationexample (No. 5) thereof and FIG. 10B is a cross-sectional view thereoftaken along an arrow of X6-X6 shown in FIG. 10A;

FIG. 11A is a plan view of a flow-out port showing a modificationexample (No. 6) thereof and FIG. 11B is a cross-sectional view thereoftaken along an arrow of X7-X7 shown in FIG. 11A;

FIG. 12A is a plan view of a flow-out port showing a modificationexample (No. 7) thereof and FIG. 12B is a cross-sectional view thereoftaken along an arrow of X8-X8 shown in FIG. 12A;

FIG. 13A is a plan view of a flow-out port showing a modificationexample (No. 8) thereof and FIG. 13B is a cross-sectional view thereoftaken along an arrow of X9-X9 shown in FIG. 13A;

FIGS. 14A and 14B are front and plan views of a touch-sensitive sheetmember 200 as a second embodiment including partial cross-sections forshowing a configuration thereof;

FIGS. 15A to 15C are process diagrams of a base member 11 showing aformation example thereof;

FIGS. 16A to 16C are state transition diagrams of the base member 11showing a function example thereof;

FIG. 17A is a plan view of a base member 11A as a modification exampleof the base member 11 and FIG. 17B is a cross-sectional view thereoftaken along an arrow of X10-X10 shown in FIG. 17A;

FIG. 18 is an exploded perspective view of an input device 300 as athird, to which the touch-sensitive sheet member 200 is applied, forshowing a configuration of the input device 300;

FIGS. 19A and 19B are plan views of mobile phones 600 in each of whichthe input device 300 is mounted for showing a configuration of themobile phones 600;

FIG. 20 is a block diagram of the mobile phone 600 showing aconfiguration of a control system of the mobile phone 600 and atouch-sensitive feed back function example thereof;

FIGS. 21A to 21E are state diagrams showing slide and press operationexamples (No. 1 thereof) in the mobile phone 600;

FIGS. 22A to 22E are state diagrams showing the slide and pressoperation examples (No. 2 thereof) in the mobile phone 600;

FIG. 23 is a flowchart showing a control example of a display unit and atouch-sensitive variable sheet unit in the mobile phone 600 at a time ofexecution of application;

FIG. 24 is an exploded perspective view of an input device 400 as afourth embodiment, to which a touch-sensitive sheet member is applied,for showing a configuration of the input device 400;

FIGS. 25A and 25B are front and plan views of the input device 400including partial cross-sections for showing an air supply examplethereof;

FIGS. 26A to 26C are plan views of mobile phones 710 in each of whichthe input device 400 is mounted for showing display examples ofoperation panel images;

FIG. 27 is a flowchart showing a control example (No. 1) of a displayunit and a layered sheet unit for representing a sense of touch in themobile phone 710 at a time of execution of application;

FIG. 28 is a flowchart showing the control example (No. 2) of thedisplay unit and the layered sheet unit for representing the sense oftouch in the mobile phone 710 at a time of the execution of application;

FIG. 29A is an exploded perspective view of a touch-sensitive sheetmember 150 as a fifth embodiment for showing a configuration thereof andFIG. 29B is a diagram showing the driving example thereof;

FIG. 30 is an exploded perspective view of an input device 500, to whichthe touch-sensitive sheet member 150 is applied, for showing aconfiguration of the input device 500;

FIGS. 31A and 31B are explanation diagrams each showing an operationexample of the input device 500;

FIG. 32A is an exploded perspective view of a touch-sensitive sheetmember 151 that is applicable to the input device 500 for showing aconfiguration thereof and FIG. 32B is a diagram showing the drivingexample thereof;

FIG. 33A is an exploded perspective view of a touch-sensitive sheetmember 152 that is applicable to the input device 500 for showing aconfiguration thereof and FIG. 33B is a diagram showing the drivingexample thereof;

FIG. 34A is an exploded perspective view of a touch-sensitive sheetmember 153 that is applicable to the input device 500 for showing aconfiguration thereof and FIG. 34B is a diagram showing the drivingexample thereof;

FIG. 35A is an exploded perspective view of a touch-sensitive sheetmember 160 as a sixth embodiment for showing a configuration thereof andFIGS. 35B and 35C are diagrams showing the driving examples thereof;

FIG. 36 is an exploded perspective view of an input device 700 as aseventh embodiment for showing a configuration thereof;

FIG. 37 is an exploded perspective view of an input device 800 as aneighth embodiment for showing a configuration thereof;

FIG. 38 is an exploded perspective view of a display device 129 with atouch-sensitive variable sheet function for showing a configurationthereof;

FIG. 39 is a partially cutaway sectional view of the display device 129showing an example of a cross-section thereof;

FIGS. 40A to 40C are data format diagrams showing multiplex examples ofdisplay data and shape presentation signals in the input device 800;

FIG. 41 is an operation flowchart showing a selection example of a senseof touch and/or a display function in the input device 800;

FIG. 42 is a partially cutaway sectional view of a display device 229with a touch-sensitive variable sheet function, which is applicable tothe input device 800, for showing a configuration of the display device229;

FIG. 43 is a partially cutaway sectional view of a display device 329with a touch-sensitive variable sheet function, which is applicable tothe input device 800, for showing a configuration of the display device329;

FIG. 44 is a partially cutaway sectional view of a display device 429with a touch-sensitive variable sheet function, which is applicable tothe input device 800, for showing a configuration of the display device429;

FIG. 45 is a partially cutaway sectional view of a display device 529with a touch-sensitive variable sheet function, which is applicable tothe input device 800, for showing a configuration of the display device529;

FIG. 46 is a partially cutaway sectional view of a display device 629with a touch-sensitive variable sheet function, which is applicable tothe input device 800, for showing a configuration of the display device629;

FIG. 47 is a block diagram of an input device 900 as a ninth embodimentfor showing a configuration thereof;

FIG. 48 is a block diagram of the input device 900 explaining anoperation example (No. 1) of the input device 900 relating to oneoperation key element;

FIG. 49 is a block diagram of the input device 900 explaining anoperation example (No. 2) of the input device 900 relating to oneoperation key element;

FIG. 50 is a flowchart showing an input processing example of the inputdevice 900;

FIGS. 51A to 51C are perspective and cross-sectional views of a mobilephone 110 as a tenth embodiment for showing a configuration thereof; and

FIGS. 52A to 52C are perspective and cross-sectional views of a variablesheet device 220 for braille as an eleventh embodiment for showing aconfiguration thereof.

DETAILED DESCRIPTION

The following will describe embodiments of a touch-sensitive sheetmember, an input device and an electronic apparatus with reference todrawings.

Embodiment 1

FIG. 1 shows a configuration of a touch-sensitive sheet member 100 as afirst embodiment. The touch-sensitive sheet member 100 shown in FIG. 1is applicable to an electronic apparatus such as a digital camera, avideo camera, a mobile phone, a mobile terminal device, a desk-top typePC, a note type PC, an automatic teller machine, and a braille blockapparatus. The touch-sensitive sheet member 100 includes a base member1, a flow channel panel 2 and an air-circulation unit 3. The base member1 constitutes a body and has a sheet shape and predetermined hardness.For the base member 1, for example, a transparent and soft siliconrubber member having hardness 20° to 40° is used.

In spots or predetermined positions of base member 1, apertures pi (i=1to 24) for representing a sense of touch are arranged. The apertures p1to p24 constitute a sense-of-touch-representing unit and havepredetermined size(s). In this embodiment, the plural apertures p1 top24 each having an aperture diameter φ of a predetermined size areperforated in the predetermined positions of the base member 1, whichconstitute the sense-of-touch-representing unit that represents a senseof touch. The apertures p1 to p12, for example, are arranged like anarray pattern in a lower region of a surface of the base member 1, theapertures p13 to p17 are arranged like a cross pattern in an upperregion of the surface thereof and the apertures p18 to p24 are alignedalong the right end side.

The flow channel panel 2 is provided in the downward of the base member1 and introduces air to a plurality of the apertures p1 to p17 and/orp18 to p24 which are perforated in the base member 1. The flow channelpanel 2 contains a substrate 2 c and a panel body 2 k having flowchannels 2 a and 2 c. The flow channel 2 a communicates to the aperturesp1 to p12 which are arranged like an array pattern in a lower region ofa surface of the base member 1 and the apertures p13 to p17 which arearranged like a cross pattern in an upper region of the surface thereof.The flow channel 2 b communicates to the apertures p18 to p24 which arealigned along the right end side thereof (referred to as FIG. 4). Thesubstrate 2 c is provided in the downward of the flow channel panel 2,but this substrate 2 c may be omitted if sufficient strength of a bottomportion of the panel body 2 k can be secured.

An air-circulation unit 3 constituting a medium-supplying unit isconnected to the flow channel panel 2 and the air-circulation unit 3sends air to the apertures p1 to p17 and/or p18 to p24 or takes in airfrom the apertures p1 to p17 and/or p18 to p24. The air-circulation unit3 includes a flow channel changeover unit 3 a and a blower 3 b. Theair-circulation unit 3 has a programmable function for sending air tothe apertures for every group such as the group of apertures p1 to p17and the group of apertures p18 to p24 which are perforated in the basemember 1 or for taking in air from the apertures for every group such asthe group of apertures p1 to p17 and the group of apertures p18 to p24.The air-circulation unit 3 may send air to the apertures p1 to p24individually or may take in air from the apertures p1 to p24individually.

In the embodiment, the apertures p1 to p12 which are arranged like anarray pattern in the lower region of the surface of the base member 1and the apertures p13 to p17 which are arranged like a cross pattern inthe upper region of the surface thereof are treated as a first group, towhich the air is sent. The apertures p18 to p24 which are aligned alongthe right end side are treated as a second group.

The flow channel changeover unit 3 a is connected to the flow channelpanel 2 and changes over the flow channels 2 a, 2 b which communicate tothe apertures p1 to p17 of the first group and the apertures p18 to p24of the second group, which are mentioned above, corresponding to anotherfunction. As a drive-power of the changeover use, for example, a sheetcoil type motor or a solenoid member applied with the same principle asthat of the sheet coil type motor may be used.

The blower 3 b constituting an air pressure adjustor is connected to theflow channel changeover unit 3 a. The blower 3 b sends the air (medium)to the seventeen apertures p1 to p17 and the seven apertures p18 to p24of the base member 1 for every group through the flow channel changeoverunit 3 a and the flow channel panel 2, or takes in the air from theapertures p1 to p17 and p18 to p24 for every group. In this embodiment,the blower 3 b supplies the air to the apertures. Alternatively, theblower may send the air to the apertures p1 to p24 individually or takesin the air from the apertures p1 to p24 individually. As the blower 3 b,a blower using a piezoelectric device is used.

FIGS. 2A and 2B show an air supply example in the touch-sensitive sheetmember 100. According to the touch-sensitive sheet member 100 shown inFIG. 2A, the blower 3 b supplies the air to the plurality of aperturesp1 to p24 of the base member 1 through the flow channel changeover unit3 a and the flow channel panel 2. The flow channel changeover unit 3 acontains a valve core portion 301, valve changeover units 302, 303,valve bodies 304, 305 and the like. The valve core portion 301 has, forexample, a rectangle sectional shape and is made of a core member thatis formed by molding a resin or a light metal by a die.

Each of the valve changeover units 302, 303 is provided so as to formroom having a fan shape within the valve core portion 301. An air-intaketube 314 is provided in the valve changeover units 302, 303 with itcommunicating to the blower 3 b and takes in the air from the blower 3b. In the valve changeover unit 302, the valve body 304 and anair-exhaust port 306 are provided. The valve body 304 operates so as toshut off or open the air-exhaust port 306 by obtaining a drive-power ofa driving unit 3 c of a motor, a solenoid or the like. The air-exhaustport 306 communicates to the flow channel 2 a. The driving unit 3 c isprovided, for example, on the rear surface side of the valve coreportion 301.

In the valve changeover unit 303, the valve body 305 and an air-exhaustport 307 are provided. The valve body 305 operates so as to shut off oropen the air-exhaust port 307 by obtaining the drive-power of thedriving unit 3 c. The air-exhaust port 307 communicates to the flowchannel 2 b. As the valve body 304 or 305, a plate rubber sheet memberhaving a long oval shape is used.

In the above-mentioned embodiment, when the valve body 304 is openedthrough the driving unit 3 c, the air supplied from the blower 3 b ispassed through the air-exhaust port 306 and the flow channel 2 a and isintroduced to the apertures p1 to p3 (not shown in FIG. 2A), theapertures p4 to p12 and the apertures p13 to p17 (not shown in FIG. 2A).Also, when the valve body 305 is opened, the air supplied from theblower 3 b is passed through the air-exhaust port 307 and the flowchannel 2 b and is introduced to the apertures P18, p19, and theapertures p20 to p24 (not shown in FIG. 2A).

When the valve bodies 304, 305 are opened at the same time, the airsupplied from the blower 3 b is passed through the air-exhaust port 306and the flow channel 2 a and is introduced to the apertures p1 to p17and at the same time, the air supplied from the blower 3 b is passedthrough the air-exhaust port 307 and the flow channel 2 b and isintroduced to the apertures p18 to p24. Also, when the valve bodies304,305 are closed at the same time, the air supply to the apertures p1to p24 stops.

Accordingly, the programmable air-circulation unit 3 is constituted tosend the air to the apertures for every group such as the plurality ofapertures p1 to p17 and the plurality of apertures p18 to p24 which areperforated in the base member 1, or to take in the air from theapertures for every group such as the apertures p1 to p17 and theapertures p18 to p24. AS shown in FIG. 2B, in the touch-sensitive sheetmember 100, the air supplied from the air-circulation unit 3 by passingit through the flow channel 2 a and the like can be blown out to theoutside from the aperture p5, the aperture p8, the aperture p10 or thelike. It should be noted that realizing air-taking from the apertures p1to p17 and the apertures p18 to p24 is allowed by exchanging theconnections of the flow channels 2 a, 2 b and the air-exhaust ports 306,307.

FIG. 3 shows a configuration of the blower 3 b. The blower 3 b shown inFIG. 3 is a blower having a piston type structure and contains anapparatus main body 311, an air-intake port 312, a valve body 313, apiston unit 314, a piezoelectric unit 315, a valve body 316, anair-exhaust port 317 and a pedestal 318 in concurrent use of a lid. Theapparatus main body 311 has a rectangular sectional shape and hasinternal volume in which the piston unit 314 is reciprocated. Theapparatus main body 311 is constituted, for example, by a housing memberformed by molding a resin or a light metal using a die.

In the apparatus main body 311, the air-intake port 312 and theair-exhaust port 317 are provided which have predetermined sizes(aperture diameters). The air-intake port 312 and the air-exhaust port317 are provided together in parallel in, for example, the up/down onone of the side surfaces of the apparatus main body 311. The aperturediameters of the air-intake port 312 and the air-exhaust port 317 areset to have the same diameter, or are set so that the aperture diameterof the air-exhaust port 317 is larger than that of the air-intake port312. The reason why the aperture diameter of the air-exhaust port 317 isset larger is because the air-exhaust resistance is decreased.

The valve body 313 is movably mounted on the air-intake port 312, and isopened when the air is taken in the apparatus main body 311. The valvebody 313 is closed when the air is released to the outside from theinside of the apparatus main body 311. In the inside of the apparatusmain body 311, the piston unit 314 having a predetermined shape isprovided. The piezoelectric unit 315 is mounted on one side of thepiston unit 314 and the piston unit reciprocates by obtaining a drivingforce of the piezoelectric unit 315.

The valve body 316 is movably mounted on the air-exhaust port 317 and isopened when the air is released to the outside from the inside of theapparatus main body 311. The valve body 316 is closed when the air istaken in the apparatus main body 311. As the valve body 313 or 316, aplate shaped rubber sheet member is used. The piezoelectric unit 315 ismounted on the pedestal 318 concurrent used as the lid body. For thepiezoelectric unit 315, a piezoelectric device (PZT: Actuator) is used.The pedestal 318 concurrent used as the lid body is assembled so as toclose the apparatus main body 311. In this manner, the blower 3 b isconstituted which can supply the air to the flow channel panel 2 throughthe flow channel changeover unit 3 a.

Although, in this embodiment, the blower 3 b of a piston type has beendescribed, the blower is not limited to this; a blower in which aVenturi effect is used may be used. A blower of Venturi type includes adiaphragm in a pump room and a Venturi tube unit is communicated to oneend of the pump room. The Venturi tube unit is provided with an intakeport and an exhaust port.

According to this blower, the diaphragm pushes air in the pump room out,so that the high speed air current occurs toward the Venturi tube unitfrom the pump room. The Venturi tube unit is designed to have anaperture diameter smaller than ones of the intake port or the exhaustport, so that the current speed of air (gas) becomes very high speed ascompared with ones of the outside of the exhaust port.

On the other hand, the outside of the exhaust port is an atmosphericpressure (one atm), but the Venturi tube unit becomes negative pressurebecause the air current speed is big. Here, Bernoulli's theorem isformed between the Venturi tube unit and the outside of the exhaustport. When an air density is made asp, the speed of the air in theVenturi tube unit is made as v1, the pressure thereof is made as P1, thespeed of the air at the outside of the exhaust port is made as v2 andthe pressure thereof is made as P2, a formula (1) is obtained from therelationship of v1>v2, P1<P2, specifically as follows.

p*v1²+2*P1=p*v2²+2*P2  (1)

The P2 is an atmospheric pressure and P1 is lower than an atmosphericpressure, so that air is taken from the intake port through the flowchannel. Specifically, the air having volume more than volume of thepushed air in the pump room is blown out of the exhaust port.

Further, when the diaphragm pulls air in the pump room, high speed aircurrent occurs toward the pump room from the Venturi tube unit. In thiscase, similarly as the above, negative pressure occurs because thecurrent speed of air of the Venturi tube unit is larger as compared withthat of air of the outside of the exhaust port. This enables air to betaken from the intake port through the flow channel. It is also possibleto apply a blower employed with such a Venturi effect to theair-circulation unit 3.

FIG. 4 shows an assembly of a base member 1 and a flow channel panel 2in the touch-sensitive sheet member 100. According to the assembly inthe touch-sensitive sheet member 100 shown in FIG. 4, the base member 1and the flow channel panel 2 are prepared. The base member 1 is formedby perforating the apertures p1 to p24 in the body for base member. Forexample, in a case in which the touch-sensitive sheet member 100 is usedas an input detection unit, which constitutes the input device, of aten-key, a cross key function, a selection key or the like of a mobilephone, the aperture p1 is perforated on the region of the base member 1in conformity with a position on which a key of numeral “1” is displayedand the aperture p2 is perforated on the region of the base member 1 inconformity with a position on which a key of numeral “2” is displayed.Further, the aperture p3 is perforated on the region of the base member1 in conformity with a position on which a key of numeral “3” isdisplayed and the aperture p4 is perforated on the region of the basemember 1 in conformity with a position on which a key of numeral “4” isdisplayed. The aperture p5 is perforated on the region of the basemember 1 in conformity with a position on which a key of numeral “5” isdisplayed and the aperture p6 is perforated on the region of the basemember 1 in conformity with a position on which a key of numeral “6” isdisplayed.

Further, the aperture p7 is perforated on the region of the base member1 in conformity with a position on which a key of numeral “7” isdisplayed and the aperture p8 is perforated on the region of the basemember 1 in conformity with a position on which a key of numeral “8” isdisplayed. The aperture p9 is perforated on the region of the basemember 1 in conformity with a position on which a key of numeral “9” isdisplayed and the aperture p10 is perforated on the region of the basemember 1 in conformity with a position on which a key of numeral “0” isdisplayed.

The aperture p11 is perforated on the region of the base member 1 inconformity with a position on which a key of numeral “#” is displayedand the aperture p12 is perforated on the region of the base member 1 inconformity with a position on which a key of numeral “*” is displayed.

Also, the aperture p13 constituting a cross key is perforated on theregion of the base member 1 in conformity with a position which a key ofdetermination “O” is displayed. The aperture p14 is perforated on theregion of the base member 1 in conformity with a position on which aleft facing arrow key is displayed and the aperture p15 is perforated onthe region of the base member 1 in conformity with a position on whichan upward facing arrow key is displayed. Further, the aperture p16 isperforated on the region of the base member 1 in conformity with aposition on which a right facing arrow key is displayed and the aperturep17 is perforated on the region of the base member 1 in conformity witha position on which a downward facing arrow key is displayed.

Further, the aperture p18 constituting a function selection key isperforated on the region of the base member 1 in conformity with aposition on which a key of “etc” is displayed and the aperture portionp19 is perforated on the region of the base member 1 in conformity witha position on which a key of “REW” is displayed. The aperture portionp20 is perforated on the region of the base member 1 in conformity witha position on which a left facing arrow stop key is displayed and theaperture portion p21 is perforated on the region of the base member 1 inconformity with a position on which a right facing arrow stop key isdisplayed. The aperture portion p22 is perforated on the region of thebase member 1 in conformity with a position on which a left facingfast-forward key is displayed and the aperture portion p23 is perforatedon the region of the base member 1 in conformity with a position onwhich a right facing fast-forward key is displayed. The aperture portionp24 is perforated on the region of the base member 1 in conformity witha position on which a stop key is displayed (see FIG. 18). Each of theapertures p1 to p24 has an aperture diameter φ.

The flow channel panel 2 is formed so that the panel body 2 k having theflow channels 2 a, 2 b is provided on the substrate 2 c. For example, acore and cavity forming a tree shaped flow channel 2 a and a linearshaped flow channel 2 b is processed. The flow channel 2 a isconstituted, for example, by flow channels 201 to 211. The flow channel2 a is formed so that the flow channels 201, 206, the flow channels 202,207, the flow channels 203, 208, the flow channels 204, 208 and the flowchannels 205, 210 are arranged from the upward region of the flowchannel 211 of the center region in order with them being perpendicularto the flow channel 211.

At a time of the mounting, the flow channel 211 of the center regionintroduces the air to the seven apertures p15, p13, p17, p2, p5, p8, p10the flow channel 201 introduces the air to the aperture p14, the flowchannel 202 introduces the air to the aperture p1, the flow channel 203introduces the air to the aperture p4, the flow channel 204 introducesthe air to the aperture p7, and the flow channel 205 introduces the airto the aperture p11.

Also, at a time of the mounting, the flow channel 206 introduces the airto the aperture p16, the flow channel 207 introduces the air to theaperture p3, the flow channel 208 introduces the air to the aperture p6,the flow channel 209 introduces the air to the aperture p9, and the flowchannel 210 introduces the air to the aperture p12. The flow channelpanel 2 is formed by die-tightening a die having such a core and cavityand by sealing a transparent resin material thereinto. The substrate 2 cmay be formed at the same time of molding the panel body 2 k with theflow channels 2 a, 2 b using the same die.

When the base member 1 and the flow channel panel 2 are prepared, thebase member 1 and the flow channel panel 2 are bonded. The base member 1is bonded onto the upper portion of the flow channel panel 2 with itcovering the flow channel panel 2. As an adhesive agent, for example, ahot melt-based resin adhesive agent, a double sided tape or the like isused to keep air-tightness. This enables a touch-sensitive sheet memberas an intermediate component in which the base member 1 is provided onthe flow channel panel 2 to be obtained. Thereafter, the air-circulationunit 3 is mounted thereon and the touch-sensitive sheet member 100 iscompleted. In this embodiment, the flow channel changeover unit 3 a andthe flow channel panel 2 are connected so that an extended portion ofthe air-exhaust port 306 of the flow channel changeover unit 3 acommunicates to the flow channel 2 a of the flow channel panel 2 andalso an extended portion of the air-exhaust port 307 communicates to theflow channel 2 b of the flow channel panel 2. A structure of theair-circulation unit 3 should be referred to FIG. 2A and FIG. 3.

It should be noted that for the base member 1 and the flow channel panel2, a transparent material is used in which the refractive index is nearapproximately 1.4 and all light transmittances is around of 70 to 95%,when a refractive index of air is made as 1 and the light transmittancethereof is made as 100%. The base member 1 preferably has thickness of0.01 to 5 mm.

As the above-mentioned base member 1, there can be used an acrylic-basedtransparent material (hereinafter, referred to as transparent material),a polycarbonate-based (PC-based) transparent material, a polyethyleneterephthalate-based (PET-based) transparent material, a polyethersulfone-based (PES-based) transparent material, a polyarylate-based(PAR-based) transparent material, a polyether ether ketone-based(PEEK-based) transparent material, a liquid crystal polymer-based(LCP-based) transparent material, a polytetrafluoroethylene-based(PTFE-based) transparent material, a polystyrene-based transparentmaterial, a styrene-based transparent material, and an urethane-basedtransparent material, a silicon-based transparent material. As theabove-mentioned base member 1, there can be also used a transparentmaterial formed by mutual synthesis or the like of all the materials ofa polytetrafluorothylene-based (PTFE-based) material, a fluorine-basedresin material, a cycloolefin polymer-based (COP-based) material, anacrylonitrile-butadiene-styrene-based (ABS-based) material and the like.Further, as the above-mentioned base member 1, there can be used atransparent material derived from one of all the above-mentionedmaterials, a non-transparent material of all the above-mentionedmaterials and a polymer alloy which is formed by mixing a materialwithin all the above-mentioned materials and rubber or the like.

Also, as the base member 1 and the flow channel panel 2, the followingsynthetic resins may be used in general (there exist materialsoverlapped with the contents mentioned above): a phenol resin (PF), anepoxy resin (EP), a melamine resin (MF), an urea resin (UF), anunsaturated polyester resin (UP), an alkyd resin, polyurethane (PUR),thermoset polyimide (PI), polyethylene (PE), high density polyethylene(HDPE), medium density polyethylene (MDPE), low density polyethylene(LDPE), polypropylene (PP), polyvinylchloride (PVC), polyvinylidenechloride, polystyrene (PS), and polyvinyl acetate (PVAc),polytetrafluoroethylene (PTFE)(Teflon-trademark), an acrylonitrilebutadiene styrene resin (ABS), an AS resin, an acrylic resin (PMMA),polyamide (PA), nylon, polyacetal (POM), polycarbonate(polycarbonate-based transparent material), modified polyphenylen ether(m-PPE, modified PPE, PPO), polybutylene terephthalate (PBT),polyethylene terephthalate (polyethylene terephthalate-based transparentmaterial), a polyethylene terephthalate material including a glass resin(polyethylene terephthalate-based transparent material-G), glass-fiberreinforced polyethylene terephthalate (GF-polyethyleneterephthalate-based transparent material), cyclic polyolefin (COP),polyphenylene sulfide (PPS), polysulfone (PSF), polyether sulfone(polyethersulfone-based transparent material), amorphous polyarylate(PAR), a liquid crystal polymer (LCP), polyether ether ketone (PEEK),thermoplastic polyimide (PI), polyamide-imide (PAI), a transparentmaterial formed by mutual synthesis or the like of all theabove-mentioned materials, a transparent material derived from one ofall the above-mentioned materials, a non-transparent material (which isused as nonskid sheet) of all the above-mentioned materials, and apolymer alloy which is formed by mixing a material within all theabove-mentioned materials and rubber or the like.

The following will describe shapes of the flow-out ports of the aperturep1 and the like with reference to FIG. 5 to FIG. 13. FIG. 5A shows ashape example of a flow-out port Q1 and FIG. 5B is a cross-section viewthereof taken along an arrow of X1-X1 shown in FIG. 5A. The flow-outport Q1 shown in FIG. 5A is formed at each of the terminal portions ofthe apertures p1 to p24 as shown in FIG. 4 and the shape thereof has abase circle. The aperture p1 or the like is formed by perforating it inthe base member 1 shown in FIG. 5B.

In this embodiment, it is possible to obtain a sense of touch by a massof air blown out of the aperture p1 or the like in a single manner. InFIG. 5 to FIG. 13, each Ia is a display region which can display oneelement of the input key, for example, the key of numeral “1”, thedetermination key of the cross key or the like. On this display regionIa displaying the key of numeral “1”, the determination key of the crosskey or the like, slide operation or press operation is executed.

FIG. 6A shows a shape example of a flow-out port Q2 as a modificationexample (No. 1) and FIG. 6B is a cross-section view thereof taken alongan arrow of X2-X2 shown in FIG. 6A. The flow-out port Q2 shown in FIG.6A has a circular shape in which triple circular members are formed. Theflow-out port Q2 is constituted by including, for example, a circularopening region of the center region, arc shaped opening regions on theconcentric circle thereof and arc shaped opening regions of the outsidethereof. Each of the triple circular members is mutually engaged andsupported by beam portions.

It should be noted that as shown in FIG. 6B, it is set such that theopening width of the outside is narrower than the opening width of theinside. In this embodiment, it is possible to obtain a multiple sense oftouch by dividing a mass of air blown out of the flow-out port Q2 inthree as compared with the sense of touch by a mass of air blown out ofthe base flow-out port Q1 in a single manner.

FIG. 7A shows a shape example of a flow-out port Q3 as a modificationexample (No. 2) and FIG. 7B is a cross-section view thereof taken alongan arrow of X3-X3 shown in FIG. 7A. The flow-out port Q3 shown in FIG.7A has many holes which are dispersed. The flow-out port Q3 isconstituted by including, for example, a large hole at the centerregion, a plurality of radially arranged holes on its concentric circleand a plurality of further radially arranged holes on the peripherythereof. It should be noted that as shown in FIG. 7B, they are set suchthat a diameter of the outside hole becomes smaller than that of theinside hole. In this embodiment, it is possible to obtain a unique senseof touch by a mass of air blown out of the flow-out port Q3 in theplural dispersing manner as compared with a mass of air blown out of thebase flow-out port Q1 in a single manner.

FIG. 8A shows a shape example of a flow-out port Q4 as a modificationexample (No. 3) and FIG. 8B is a cross-section view thereof taken alongan arrow of X4-X4 shown in FIG. 8A. The flow-out port Q4 shown in FIG.8A has a triple concentric circle members. The flow-out port Q4 isconstituted by including, for example, small circular opening at acenter region, arc shaped openings on the concentric circle thereof andarc shaped openings on the outside thereof. The concentric circlemembers is respectively engaged and supported to the base member 1 bybeam portions. It should be noted that as shown in FIG. 8B, the openingwidth of the inside is narrower than the opening width of the outside.In this embodiment, it is possible to obtain a multiple sense of touchby a mass of air blown out of the flow-out port Q4 in the pluraldispersing manner as compared with a mass of air blown out of the baseflow-out port Q1 in a single manner.

FIG. 9A shows a shape example of a flow-out port Q5 as a modificationexample (No. 4) and FIG. 9B is a cross-section view thereof taken alongan arrow of X5-X5 shown in FIG. 9A. The flow-out port Q5 shown in FIG.9A has many holes which are dispersed. The flow-out port Q5 isconstituted by including, for example, a small hole at a center region,a plurality of radially arranged holes on the concentric circle thereofand, a plurality of further radially arranged holes in the peripherythereof. It should be noted that as shown in FIG. 9B, they are set suchthat the aperture diameter of the outside hole becomes larger than theaperture diameter of the inside hole. In this embodiment, it is possibleto obtain a unique sense of touch by a mass of air blown out of theflow-out port Q5 in the plural dispersing manner as compared with a massof air blown out of the base flow-out port Q1 in a single manner.

FIG. 10A shows a shape example of a flow-out port Q6 as a modificationexample (No. 5) and FIG. 10B is a cross-section view thereof taken alongan arrow of X6-X6 shown in FIG. 10A. The flow-out port Q6 shown in FIG.10A has a single hole which has a conical shaped inner section. In thisembodiment, it is possible to obtain a unique sense of touch by a massof air blown out of the flow-out port Q6 at high speed as compared witha mass of air blown out of the base flow-out port Q1 in a single manner.

FIG. 11A shows a shape example of a flow-out port Q7 as a modificationexample (No. 6) and FIG. 11B is a cross-section view thereof taken alongan arrow of X7-X7 shown in FIG. 11A. The flow-out port Q7 shown in FIG.11A has a single hole which has a reverse dish shaped inner section. Inthis embodiment, it is possible to obtain a unique sense of touch by theraised base member 1 in addition to a mass of air blown out of theflow-out port Q7 at high speed as compared with a mass of air blown outof the base flow-out port Q1 in a single manner.

FIG. 12A shows a shape example of a flow-out port Q8 as a modificationexample (No. 7) and FIG. 12B is a cross-section view thereof taken alongan arrow of X8-X8 shown in FIG. 12A. The flow-out port Q8 shown in FIG.12A has a shape of circular arcs. A center member C1 is engaged andsupported to the base member 1 by beam portions. The aperture p1 or thelike is formed by perforating it in the base member 1 shown in FIG. 12B.In this embodiment, it is possible to obtain a unique sense of touch bya mass of air blown out of the flow-out port Q8 in the circular shape ascompared with a mass of air blown out of the base flow-out port Q1 in asingle manner.

FIG. 13A shows a shape example of a flow-out port Q9 as a modificationexample (No. 8) and FIG. 13B is a cross-section view thereof taken alongan arrow of X9-X9 shown in FIG. 13A. The flow-out port Q9 shown in FIG.13A has many holes which are arranged as being a circle. The aperture p1or the like is formed by perforating a plurality of small holes in thebase member 1 shown in FIG. 13B. In this embodiment, it is possible toobtain a unique sense of touch by a plurality of masses of air blown outof the flow-out port Q9 as the circle as compared with a mass of airblown out from the base flow-out port Q1 in a single manner.

In this manner, according to the touch-sensitive sheet member 100 as thefirst embodiment, the flow channel panel 2 is provided which introducesthe air to twenty four apertures p1 to p24 perforated in the base member1 and the blower 3 b utilizing the piezoelectric device is used as theair-circulation unit 3 and is connected to the flow channel panel 2 sothat the blower 3 b sends the air to the apertures p1 to p24 of the basemember 1 through the flow channel panel 2 for every group.

Consequently, even if the surface of the base member 1 is observed to bea flat shape, when the operator's hand (finger) touches the surfacethereof actually and slides from the base member 1 to the apertures p1or the like for representing a sense of touch, in the predeterminedposition of the base member 1, the apertures p1 to p24 can represent thesense of touch which gives the concave and convex touch feeling by theair blown out of the apertures p1 to p24 with respect to the operator'sfinger or the like (operation body). Such a touch-sensitive sheet member100 may be applied to a programmable nonskid sheet at the grip portionof various kinds of electronic apparatus housing, a programmabletouch-sensitive input sheet for icon touch in an input device or thelike. Thus, it becomes possible to provide the input device includingthe programmable touch-sensitive input sheet.

Embodiment 2

FIGS. 14A and 14B show a configuration of a touch-sensitive sheet member200 as a second embodiment. In this embodiment, thesense-of-touch-representing unit contains bag portions q1 to q24 forrepresenting a sense of touch, each bag portion having a predeterminedsize and being arranged at a predetermined position of a base member 11.

The touch-sensitive sheet member 200 shown in FIG. 14A is applicable toan input device which is mounted on an electronic apparatus such as adigital camera, a video camera, a mobile phone, a mobile terminaldevice, a desk-top type PC, a note type PC, an automatic teller machineor the like. The touch-sensitive sheet member 200 includes the basemember 11, the flow channel panel 2 and the air-circulation unit 3.

The air-circulation unit 3 constitutes the medium-supplying unit andoperates such that the air is sent to the bag portions q1 to q24 (onlyq5, q8, q10 are shown in FIG. 14A). In this embodiment, theair-circulation unit 3 has a programmable function for sending the airto the plurality of bag portions q1 to q24 arranged in the base member11 individually or for every group. In this embodiment, the flow channelpanel 2 which introduces the air to the plurality of bag portions q1 toq24 arranged in the base member 11 is also provided. The air-circulationunit 3 contains a blower 3 b (air pressure generator) utilizing apiezoelectric device.

The blower 3 b is connected to the flow channel panel 2 through a flowchannel changeover unit 3 a shown in the FIG. 14B. The blower 3 b sendscompressed air to the plurality of bag portions q1 to q24 in the basemember 11 by dividing those into two groups through the flow channelpanel 2. It should be noted that in this embodiment, the members havingthe same name and numeral as those used in the first embodiment havealso the same function, so that the explanation thereof will be omitted.

In the above-mentioned embodiment, when the valve body 304 is openedthrough the driving unit 3 c, the air supplied from the blower 3 b isintroduced to the bag portions q1 to q3 (not shown in drawings), the bagportions q4 to q12 and the bag portions q13 to q17 (not shown indrawings) by passing through the air-exhaust port 306 and the flowchannel 2 a. Also, when the valve body 305 is opened, the air suppliedfrom the blower 3 b is introduced to the bag portions q18, q19, the bagportions q20 to q24 (not shown in the drawings) by passing through theair-exhaust port 307 and the flow channel 2 b.

When the valve bodies 304, 305 are opened at the same time, the airsupplied from the blower 3 b is introduced to the bag portions q1 to q17by passing through the air-exhaust port 306 and the flow channel 2 a andat the same time, is introduced to the bag portions q18 to q24 bypassing through the air-exhaust port 307 and the flow channel 2 b. Also,when the valve bodies 304, 305 are closed at the same time, the airsupply to the bag portions q1 to q24 is stopped.

In this manner, the programmable air-circulation unit 3 is constitutedto send the air to the plurality of bag portions q1 to q17 and theplurality of bag portions q18 to q24, which are arranged in the basemember 11, for every group or to take the air from the bag portions q1to q17 and the bag portions q18 to q24. In the touch-sensitive sheetmember 200 shown in FIG. 14A, it is possible to fill the bag portion q5,the bag portion q8, the bag portion q10 and the like up with the airsupplied from the air-circulation unit 3 by passing through the flowchannel 2 a and the like.

The following will describe a formation method of the base member 11with reference to FIGS. 15A to 15C. FIGS. 15A to 15C show a formationexample of the base member 11. In this example, there are formed a firstsheet member 11 a in which the bag portions q7, q11 and the like shownin FIG. 14B are halved in the horizontal direction and a second sheetmember 11 b in which the bag portions q7, q11 and the like shown in FIG.14B are also halved in the horizontal direction. For example, byprocessing a die member, a core and a cavity are prepared which formdish shapes modeling the bag portions q7, q11 and the like. Bydie-tightening a die having such a core and cavity and by sealing atransparent resin material therein, there is formed the first sheetmember 11 a having the concave shaped half-cut bag portions q7, q11 asshown in FIG. 15A in which the bag portions q7, q11 and the like shownin FIG. 14B are halved in the horizontal direction.

Next, there is formed the second sheet member 11 b having air insertionportions 11 c and the concave shaped half-cut bag portions q7, q11 whichbecome partners of the concave shaped half-cut bag portions q7, q11 andthe like shown in FIG. 15A. For example, by processing a die member, acore and a cavity are prepared which form dish shapes modeling thehalf-cut bag portions q7, q11 and the like and shapes of the airinsertion portions 11 c. By die-tightening a die having such a core andcavity and by sealing a transparent resin material therein, there isformed the second sheet member 11 b having the air insertion portions 11c and the concave shaped half-cut bag portions q7, q11 shown in FIG.15B.

Thereafter, the base member 11 having the bag portions q1 to q24 isformed by bonding the first and second concave shaped sheet members 11a, 11 b. At that time, the concave region of the half-cut bag portionsq7, q11 of the first sheet member 11 a and the concave region of thehalf-cut bag portions q7, q11 of the second sheet member 11 b are bondedwith them being positioned. For the bonding of the first sheet member 11a and the second sheet member 11 b, a hot melt-based resin adhesiveagent or a double-sided tape is used. Thus, the base member 11 havingthe plurality of bag portions q1 to q24 as shown in FIG. 14A iscompleted.

The following will describe a function example of the base member 11with reference to FIGS. 16A to 16C. FIGS. 16A to 16C show a functionexample of the base member 11. The bag portion q11 or the like shown inFIG. 16A is a state in which the air is not filled up. In this state,when an operator presses the bag portion q11 or the like, he or she canobtain any sense of touch of concave feeling. The bag portion q11 or thelike shown in FIG. 16B is a state in which the air is filled up. The bagportion q11 or the like is filled up with compressed air constantly fromthe air-circulation unit 3 shown in FIG. 14B through the flow channelchangeover unit 3 b.

In this example, when the operator touches the bag portion q11 or thelike of a state of being filled up with the air shown in FIG. 16C withthe finger or the like (operation body), he or she can obtain any senseof touch of concave and convex feeling by a protuberant shape dependingon the swelled-up bag portion q11 or the like with respect to theoperator's finger 30 a. Thus, it is possible to execute the slideoperation and the press operation accompanied with an elastic feeling.

FIGS. 17A and 17B show a modification example of the base member 11. Thebase member 11A as shown in FIG. 17A is equal to a reverse dish shapedbag body which does not have the flow-out port Q7 shown in FIG. 11A. Thesheet shaped base member 11A having such a half-cut bag portion q7 shownin FIG. 17B is formed so as to be formed as being shown in FIG. 15A andis bonded to the panel body 2 k of the flow channel panel 2 shown inFIG. 14A without forming the half-cut bag portion q7 or the like of thepartner as shown in FIG. 15B, thereby enabling a touch-sensitive sheetmember. This touch-sensitive sheet member, not shown, is the device inwhich the sheet shaped base member 11A having the half-cut bag portionq7 shown in FIG. 17B is bonded to the panel body 2 k of the flow channelpanel 2 shown in FIG. 14A. It should be noted that each of the signs,“Ia” in FIGS. 17A and 17B indicates a display region of the key ofnumeral “1” or the like which forms the icon image. Even by thisstructure, it is possible to obtain a unique sense of touch by theswelled-up base member 11A.

In this manner, according to the touch-sensitive sheet member 200 as thesecond embodiment, the blower 3 b comes to send the compressed air tothe bag portions q1 to q24 for every group through the flow channelchangeover unit 3 a. Consequently, in the spots of the base member 11 orthe predetermined positions of the base member 11, it becomes possibleto represent the sense of touch for giving the concave and convexfeeling by the protuberant shape depending on each of the swelled-up bagportions q1 to q24 or by the original shape in a case of no ventilationwith respect to the operator's finger or the like (operation body).Thus, it becomes possible to provide the input device having theprogrammable touch-sensitive input sheet.

Embodiment 3

FIG. 18 shows a configuration of a third embodiment of an input device300 according to the embodiment to which the touch-sensitive sheetmember 200 is applied. In this embodiment, the input device 300 whichcan carry out an operation panel building mode is provided. The inputdevice 300 can select a first group of seventeen element bag portions E1to E17 and/or a second group of eight element bag portions E18 to E25,which are provided on the same plane of a base member 101.

The input device 300 shown in FIG. 18 inputs any information by theslide and/or press operation depending on the finger or the like of theoperator 30 (operation body). The input device 300 includes a displayunit 29, an input detection unit 45 and a touch-sensitive variable sheetunit 103.

The display unit 29 has an operation surface and displays a plurality ofpush button switch images at a time of the input operation. The pushbutton switch images constitute icon images for the input operation. Thepush button switch images include a key K1 of numeral “1” to a key K10of numeral “0”, a key K11 of symbol “*”, a key K12 of a symbol “#” orthe like, a key K13 of determination “O” of a cross key, a left facingarrow key K14 thereof, an upward facing arrow key K15 thereof, a rightfacing arrow key K16 thereof, a downward facing arrow key K17 thereof, akey K18 of “etc”, a key K19 of “REW”, a left facing arrow stop key K20,a right facing arrow stop key K21, a left facing fast-forward key K22, afast-forward key K23, a reproduction key K24 and a stop key K25 or thelike. As the display unit 29, a color organic EL display device or aliquid crystal display device (LCD device) is used.

The input detection unit 45 which constitutes the detection unit isprovided on the upper portion of the display unit 29. The inputdetection unit 45 includes the operation surface. The input detectionunit 45 is provided on the upper portion of the display unit 29 andoperates so as to detect the slide position of the operator's finger orthe like. As the input detection unit 45, for example, a capacitivetouch panel is used. With respect to the input detection unit 45,anything is available only if the cursoring and the selection functioncan be distinguished. For example, other than the capacitive inputdevice, it also may be a resistive touch panel, an input device of asurface acoustic wave system (SAW) or an optical system, a tact switchof a multi stage system or the like. Preferably, it may be enough if theinput device has a constitution by which position detection informationand press detection information can be applied to a control system.

The transparent touch-sensitive variable sheet unit 103 constituting thetouch-sensitive sheet member is provided on the upper portion of theinput detection unit 45. The touch-sensitive variable sheet unit 103 isprovided so as to cover the whole of the input detection unit 45 and theoperator performs any slide and/or press operation along the operationsurface of the display unit 29. It is needless to say that thetouch-sensitive variable sheet unit 103 may cover a portion of the inputdetection unit 45. The touch-sensitive variable sheet unit 103 isprovided with the embodiment of the touch-sensitive sheet member 200having a bag structure.

In this embodiment, the touch-sensitive variable sheet unit 103 containsa base member 101 which has predetermined hardness and also a pluralityof concave portions of a rectangular dish shape and which is used as theflow channel panel 2 concurrently, a sheet shaped film portion 5 for alid which covers the upper portion of the base member 101 in goodair-tightness, and an air-circulation unit 3 which supplies the air to aplurality of the element bag portions E1 to E25 for representing a senseof touch which are constituted by the base member 101 and the filmportion 5. The air-circulation unit 3 includes a flow channel changeoverunit 3 a and a blower 3 b as shown in FIG. 2. The blower 3 b having thepiezoelectric unit 315 is used. The element bag portions E1 to E25constituted by the base member 101 and the film portion 5 havepredetermined sizes and are distributed in spots of the base member 101or predetermined positions thereof.

For example, the base member 101 includes the plurality of the elementbag portions E1 to E25 which are distributed at the predeterminedpositions by forming the concave portions of the predetermined sizes.The element bag portions E1 to E25 constitutes thesense-of-touch-representing unit. In this embodiment, the element bagportions E1 to E12 for the keys of the numerals “0” to “9”, the key ofsymbol “*” and the key of symbol “#” and the like and the element bagportions E13 to E17 for the cross key corresponding to the icon imagefor the input operation have, for example, square concave shapes.

The element bag portion E18 for the key of “etc” for function selection,the element bag portion E19 for the key of “REW”, the element bagportion E20 for the left facing arrow stop key thereof, the element bagportion E21 for the right facing arrow stop key thereof, the element bagportion E22 for the left facing fast-forward key thereof, the elementbag portion E23 for the fast-forward key thereof, the element bagportion E24 for the reproduction key thereof and the element bag portionE25 for the stop key thereof have also the square concave shape. Therespective element bag portions E1 to E25 are formed in the base member101 having the hardness of 20° to 40° which is used as the flow channelpanel 2 concurrently.

The above-mentioned element bag portions E1 to E25 are arrangedcorresponding to the keys K1 to K25 of various kinds of functions. Forexample, the element bag portion E1 is arranged so as to be positionedon the key K1 of numeral “1” of the icon image displayed on the displayunit 29. The element bag portion E2 is arranged so as to be positionedon the key K2 of numeral “2” of the icon image displayed on the displayunit 29. The element bag portion E3 is arranged so as to be positionedon the key K3 of numeral “3” of the icon image displayed on the displayunit 29. The element bag portion E4 is arranged so as to be positionedon the key K4 of numeral “4” of the icon image displayed on the displayunit 29. The element bag portion E5 is arranged so as to be positionedon the key K5 of numeral “5” of the icon image displayed on the displayunit 29. The element bag portion E6 is arranged so as to be positionedon the key K6 of numeral “6” of the icon image displayed on the displayunit 29. The element bag portion E7 is arranged so as to be positionedon the key K7 of numeral “7” of the icon image displayed on the displayunit 29. The element bag portion E8 is arranged so as to be positionedon the key K8 of numeral “8” of the icon image displayed on the displayunit 29. The element bag portion E9 is arranged so as to be positionedon the key K9 of numeral “9” of the icon image displayed on the displayunit 29. The element bag portion E10 is arranged so as to be positionedon the key K10 of numeral “0” of the icon image displayed on the displayunit 29.

Also, the element bag portion E11 is arranged so as to be positioned onthe key K11 of symbol “*” of the icon image displayed on the displayunit 29. The element bag portion E12 is arranged so as to be positionedon the key K12 of symbol “#” of the icon image displayed on the displayunit 29. The element bag portion E13 is arranged so as to be positionedon the key K13 of determination “O” of the icon image of the cross keydisplayed on the display unit 29. The element bag portion E14 isarranged so as to be positioned on the left facing arrow key K14 of theicon image displayed on the display unit 29. The element bag portion E15is arranged so as to be positioned on the upward facing arrow key K15 ofthe icon image displayed on the display unit 29. The element bag portionE16 is arranged so as to be positioned on the right facing arrow key K16of the icon image displayed on the display unit 29. The element bagportion E17 is arranged so as to be positioned on the downward facingarrow key K17 of the icon image displayed on the display unit 29.

Further, the element bag portion E18 is arranged so as to be positionedon the key K18 of “etc” of the icon image displayed on the display unit29. The element bag portion E19 is arranged so as to be positioned onthe key K19 of “REW” of the icon image displayed on the display unit 29.The element bag portion E20 is arranged so as to be positioned on theleft facing arrow stop key K20 of the icon image displayed on thedisplay unit 29. The element bag portion E21 is arranged so as to bepositioned on the right facing arrow stop key K21 of the icon imagedisplayed on the display unit 29. The element bag portion E22 isarranged so as to be positioned on the left facing fast-forward key K22of the icon image displayed on the display unit 29. The element bagportion E23 is arranged so as to be positioned on the fast-forward keyK23 of the icon image displayed on the display unit 29. The element bagportion E24 is arranged so as to be positioned on the reproduction keyK24 of the icon image displayed on the display unit 29. The element bagportion E25 is arranged so as to be positioned on the stop key K18 ofthe icon image displayed on the display unit 29.

In this embodiment, the film portion 5 constituting the lid portion isprovided on an upper portion of the base member 101 having the elementbag portions E1 to E25. As the film portion 5, there is used atransparent material having transmissivity and a refractive index whichare approximately equal to transmissivity and a refractive index of thebase member 101. There is used, for example, a “zeonor” of the filmhaving thickness of around 25 μm. The hardness thereof is around 20° to40°.

When the input device 300 is constituted in this manner, the blower 3 bcomes to send the compressed air to the element bag portions E1 to E25for every group. Consequently, in the predetermined positions of thebase member 101, the element bag portions E1 to E25 allows forpresenting the sense of touch for giving the concave and convex feelingby the protuberant shape depending on the swelled-up element bagportions E1 to E25 or by the original shape in a case of no ventilationwith respect to the operator's finger or the like (operation body).

FIGS. 19A and 19B each shows a configuration of a mobile phone 600 inwhich the input device 300 is mounted. The mobile phone 600 shown inFIG. 19A constitutes the electronic apparatus. According to the mobilephone 600, on the display unit 29 including the operation surface, thereare displayed the icon images such as the key K1 of numeral “1” to keyK10 of numeral “0”, the key K11 of symbol “*”, the key K12 of symbol “#”or the like, the key K13 of determination “O” of the cross key, the leftfacing arrow key K14 thereof, the upward facing arrow key K15 thereof,the right facing arrow key K16 thereof and the downward facing arrow keyK17 thereof, which form a first group. These key icon images of thefirst group are, for example, displayed on the display unit 29 whenapplication #A is executed.

In this embodiment, the display region of the key K1 of numeral “1”corresponds to the element bag portion E1 shown in FIG. 18, andsimilarly, the display region of the key K2 of numeral “2” correspondsto the element bag portion E2 shown in FIG. 18. The display region ofthe key K3 of numeral “3” corresponds to the element bag portion E3shown in FIG. 18. The display region of the key K4 of numeral “4”corresponds to the element bag portion E4 shown in FIG. 18. The displayregion of the key K5 of numeral “5” corresponds to the element bagportion E5 shown in FIG. 18. The display region of the key K6 of numeral“6” corresponds to the element bag portion E6 shown in FIG. 18. Thedisplay region of the key K7 of numeral “7” corresponds to the elementbag portion E7 shown in FIG. 18. The display region of the key K8 ofnumeral “8” corresponds to the element bag portion E8 shown in FIG. 18.The display region of the key K9 of numeral “9” corresponds to theelement bag portion E9 shown in FIG. 18. The display region of the keyK10 of numeral “0” corresponds to the element bag portion E10 shown inFIG. 18. The respective display regions enable the concave and convextouch feeling to be given to the operator's finger when the slideoperation or the press operation is executed.

Further, the display region of the key K11 of symbol “*” corresponds tothe element bag portion E11 shown in FIG. 18 and the display region ofthe key K12 of symbol “#” corresponds to the element bag portion E12.The respective display regions enable the concave and convex touchfeeling to be given to the operator's finger. Similarly, the displayregion of the key K13 of determination “O” which forms the cross keycorresponds to the element bag portion E13, the display region of theleft facing arrow key K14 thereof corresponds to the element bag portionE14 and the display region of the upward facing arrow key K15 thereofcorresponds to the element bag portion E15. Further, the display regionof the right facing arrow key K16 thereof corresponds to the element bagportion E16 and the display region of the downward facing arrow key K17thereof corresponds to the element bag portion E17. When the slideoperation or the press operation is executed, it is constituted suchthat the respective display regions enable the concave and convex touchfeeling to be given to the operator's finger. The concave and convextouch feeling in such a first group occurs based on a fact in which theair-circulation unit 3 is controlled such that the flow channelchangeover unit 3 a selects the flow channel 2 a to send the air to thebase member 101 which is concurrently used as the flow channel panel.

According to the mobile phone 600 shown in FIG. 19B, on the display unit29 including the operation surface, there are displayed the icon imagesof the key K18 of “etc”, the key K19 of “REW”, the left facing arrowstop key K20, the right facing arrow stop key K21, the left facingfast-forward key K22, the fast-forward key K23, the reproduction keyK24, the stop key K25, which form a second group, and at the same time,the vide of the reproduction application or the like. These key iconimages of the second group, for example, are displayed on the displayunit 29 when application #B is executed.

In this embodiment, the display region of the key K18 of “etc”corresponds to the element bag portion E18 shown in FIG. 18 andsimilarly, the display region of the key K19 of “REW” corresponds to theelement bag portion E19. The display region of the left facing arrowstop key K20 corresponds to the element bag portion E20, the displayregion of the right facing arrow stop key K21 corresponds to the elementbag portion E21 and the display region of the left facing fast-forwardkey K22 corresponds to the element bag portion E22. Further, the displayregion of the fast-forward key K23 corresponds to the element bagportion E23, the display region of the reproduction key K24 correspondsto the element bag portion E24 and the display region of the stop keyK25 corresponds to the element bag portion E25. When the slide operationor the press operation is executed, the respective display regionsenable the concave and convex touch feeling to be given to theoperator's fingers. The concave and convex touch feeling in such asecond group occurs on a fact in which the air-circulation unit 3 iscontrolled such that the flow channel changeover unit 3 a selects theflow channel 2 b to send the air to the base member 101 which isconcurrently used as the flow channel panel.

In this manner, according to the mobile phone 600, the representationposition of the convex and concave shape thereof is changed depending onthe states of the applications #A and #B of the operation key screen, sothat in case of the comparison with the key board of the past or thefixation system of the past system, in the same area, specifically “inthe sense of touch-like meaning for representing the surface shape”, itbecomes possible to constitute various input units.

The following will describe a control system or the like of the mobilephone 600. FIG. 20 shows a configuration of the control system of themobile phone 600 and the touch-sensitive feed back function examplethereof.

In this example, the amount of air which is supplied to the element bagportions E1 to E25 for representing a sense of touch is adjusted forevery group by controlling the piezoelectric unit 315 of thetouch-sensitive variable sheet unit 103, thereby enabling the changedsense of touch to be given to the operator's finger 30 a (operationbody).

The mobile phone 600 shown in FIG. 20 contains a control unit 15, areceiving unit 18, a transmitting unit 22, an antenna diplexer 23, theinput detection unit 45, the display unit 29, a power supply unit 33, acamera 34, a memory unit 35, a speaker 36 a for an incoming melody, aspeaker 36 b with actuator function and the touch-sensitive variablesheet unit 103. The input detection unit 45, the display unit 29 and thetouch-sensitive variable sheet unit 103 constitute the input device 300.

The input detection unit 45 detects a slide position and a press by thefinger 30 a of the operator 30 and outputs at least a position detectionsignal S1 showing the slide position and a press detection signal S2showing a pressing force F to the control unit 15. For the inputdetection unit 45, there is used a capacitive input device, a resistiveinput device, an input device of surface acoustic wave system (SAW), aninput device of an optical system, an input device of a multi-stagessystem tact switch or the like.

The input detection unit 45 is connected to the control unit 15. Thecontrol unit 15 includes an image-processing unit 26, an A/D driver 31,a CPU 32 and a storage unit 37. The A/D driver 31 receives the positiondetection signal Si and the press detection signal S2 from the inputdetection unit 45. The A/D driver 31 converts an analog signal composedof the position detection signal Si and the press detection signal S2 todigital data in order to distinguish the function of the cursoring andthe function of the icon selection. Other than this, the A/D driver 31calculates the digital data, detects which is a cursoring input or iconselection information, and supplies flag data D3 by which the cursoringinput or the icon selection is distinguished, the position detectioninformation D1 or the press detection information D2 to the CPU 32.These calculations may be executed in the CPU 32.

The A/D driver 31 is connected with the CPU 32. The CPU 32 controls thewhole of the mobile phone based on a system program. The memory unit 35stores system program data for controlling the whole of the mobilephone. A RAM, which is not shown, is used as a work memory. The CPU 32,at the same time when turning the power ON, reads the system programdata out of the memory unit 35 and expands the program data in the RAM,turns on the system and controls the whole of the mobile phone.

For example, the CPU 32 receives the position detection information D1,press detection information D2 and flag data D3 (hereinafter, simplyreferred to as the input data) from the A/D driver 31 and controls so asto supply a predetermined instruction data D to the devices of the powersupply unit 33, the camera 34, the memory unit 35, the storage unit 37,an image-and-audio-processing unit 44, the touch-sensitive variablesheet unit 103 or the like. The CPU 32 also takes-in the reception datafrom the receiving unit 18 and transfers the transmission data to thetransmitting unit 22.

In this embodiment, the CPU 32 is connected to the touch-sensitivevariable sheet unit 103, in addition to the input detection unit 45,which under a driving control of the CPU 32, adjusts an amount of airwhich is supplied to the element bag portions E1 to E25 for representinga sense of touch for every group through the piezoelectric unit 315,thereby enabling the sense of touch which is given to the operator'sfinger 30 a (operation body) to be changed.

The CPU 32, for example, compares the press detection information D2obtained from the input detection unit 45 with a preset press judgmentthreshold Fth and based on the comparison result thereof, outputs apredetermined instruction data D to the touch-sensitive variable sheetunit 103 to driving-control the piezoelectric unit 315 thereof. Here,when the sense of touch transmitted from the input detection surface inthe press position of the input detection unit 45 is supposed to be as#a and #b, the sense of touch #a is provided by changing the inputdetection surface corresponding to the pressing force F of theoperator's finger 30 a in the press position thereof from a vibrationpattern with a low frequency and also small amplitude to a vibrationpattern with a high frequency and also large amplitude.

Also, the sense of touch #b is provided by changing the input detectionsurface corresponding to the pressing force F of the operator's finger30 a in the press position thereof from a vibration pattern with a highfrequency and also large amplitude to a vibration pattern with a lowfrequency and also small amplitude. These vibration pattern outputcontrols in the input detection surface are executed by executing thedriving control by the piezoelectric unit 315 of the touch-sensitivevariable sheet unit 103. It is needless to say that the storage unit 37may be controlled so as to vibrate the speaker 36 b with actuatorfunction. It should be noted that the vibration control of the speaker36 b may be omitted. In a case in which the touch-sensitive variablesheet unit 103 is driving-controlled, the medium is air and the amountthereof is adjusted and controlled, so that it becomes possible topresent stronger sense of touch as compared with the vibration of thespeaker 36 b.

The above-mentioned CPU 32 is connected to the display unit 29 and thememory unit 35 which stores display information D4 for displaying thedisplay screen for input item selection, for example,three-dimensionally, control information Dc relating to the selectionposition and the vibration mode of the icon corresponding to the displayinformation D4 and the like for every display screen. The controlinformation Dc includes a plurality of specific vibration waveformswhich generates a plurality of different senses of touch synchronizedwith application (three-dimension-like display and various kinds ofdisplay contents) in the display unit 29 and an algorithm that sets thespecific sense-of-touch generation mode for every application. As thememory unit 35, an EEPROM, ROM, RAM or the like is used.

In this embodiment, the CPU 32 executes the display control of thedisplay unit 29, the driving control of the touch-sensitive variablesheet unit 103 and/or the output control of the speaker 36 b withactuator function based on the position detection information D1, thepress detection information D2 and the flag data D3 which are receivedfrom the A/D driver 31.

For example, the CPU 32 controls the air-circulation unit 3 so as tosupply the air to the element bag portions E1 to E25 for presenting thesense of touch of the touch-sensitive variable sheet unit 103corresponding to the image contents displayed on the display unit 29, sothat the element bag portions E1 to E25 are available at predeterminedpositions of the base member 101 corresponding to the image contents.Also, the CPU 32 controls the piezoelectric unit 315 of thetouch-sensitive variable sheet unit 103 and adjusts the amount of airwhich is supplied to the element bag portions E1 to E25 for representingthe sense of touch for every group based on the position detectioninformation D1 and the press detection information D2 which are receivedfrom the input detection unit 45, so that the sense of touch which isgiven to the operator's finger 30 a (operation body) is changed.

Further, the CPU 32 may read the control information Dc out of thememory unit 35, access the storage unit 37 and supply a vibrationgeneration signal Sout2 to the speaker 36 b with actuator function. Thiscontrol may be omitted.

The CPU 32, further, executes the driving control of the piezoelectricunit 315 and/or the read-out control of the storage unit 37 so as tocontrol the touch-sensitive variable sheet unit 103 and/or the speaker36 b to start up the sense of touch #a when the input detection unit 45detects the press detection information D2 which exceeds the pressjudgment threshold Fth and thereafter, so as to control thetouch-sensitive variable sheet unit 103 and/or the speaker 36 b to startup the sense of touch #b when the input detection unit 45 detects thepress detection information D2 which is equal to or less than the pressjudgment threshold Fth. This control enables to be generated a uniquevibration pattern in conformity with the “pressing force” of theoperator's finger 30 a or the like.

The CPU 32 is connected to the storage unit 37 of which vibrationcontrol data Da is read out based on the control information Dc from theCPU 32. The vibration generation data Da is also outputted to thetouch-sensitive variable sheet unit 103 through the CPU 32. Thevibration generation data Da has an output waveform composed of asinusoidal waveform, a saw-tooth wave, pulse wave, a rectangular wave orthe like. The storage unit 37 is connected to theimage-and-audio-processing unit 44. Respective items of vibrationgeneration data Da are supplied to the image-and-audio-processing unit44. The items of the vibration generation data Da thereof areaudio-processed (digital-analogue conversion, amplification or the like)to become a vibration generation signal Sout2 that is supplied to thespeaker 36 b with actuator function. It is constituted such that thespeaker 36 b is vibrated based on the vibration generation signal Sout2.

In this embodiment, the storage unit 37 stores the press judgmentthreshold Fth corresponding to each application. For example, the pressjudgment threshold Fth is stored beforehand in a ROM or the likeprovided in the memory unit 35 as trigger parameter. The CPU 32 readspress judgment threshold Fth out of the storage unit 37 and receives thepress detection information D2 from the A/D driver 31. The CPU 32compares the preset press judgment threshold Fth with the pressing forceF obtained from the press detection information D2 which is receivedfrom the A/D driver 31 and executes the judgment processing of Fth>F,the judgment processing of Fth≦F or the like.

For example, when the press judgment threshold Fth=100 [gf] is set inthe storage unit 37, it is constituted such that the input detectionsurface vibrates based on the vibration pattern for obtaining a sense oftouch like a classic switch. Also, when the press judgment thresholdFth=20 [gf] is set, it is constituted such that the input detectionsurface vibrates based on the vibration pattern for obtaining a sense oftouch like a cyber switch.

The CPU 32 is connected to an image-processing unit 26, other than thestorage unit 37, in which the display information D4 for displaying thebutton icon or the like three-dimensionally is image-processed. Theimage-processed display information D4 is supplied to the display unit29. In this embodiment, the CPU 32 display-controls the display unit 29so as to display the button icon in the display screenthree-dimensionally with it having the perspective in the depthdirection.

The input device 300 thus constituted is input-operated on the displayscreen for input item selection accompanied with the sense of touch bypressing down (contacting) one of the plurality of button iconsdisplayed on the display screen and by pushing-down the input detectionunit 45 on the display screen in the Z-direction. The operator 30 feelsvibration for every button icon as the sense of touch by receivingvibration at the finger 30 a thereof.

Each function is judged by the sense of sight depending on the eyes ofthe operator for the display contents of the display unit 29 and by thesense of hearing depending on the ears of the operator for the soundrelease from the speakers 36 a, 36 b or the like. To the above-mentionedCPU 32, the display unit 29 and the input detection unit 45 constitutingthe operation panel 98 are connected and for example, the operationpanel 98 is used when a phone number of the partner is inputtedmanually. The display unit 29 may display a received image based on animage signal Sv other than the above-mentioned icon selection screen.

Also, the antenna 16 shown in FIG. 20 is connected to the antennadiplexer 23 and receives a radio wave from the partner through a basestation thereof or the like when receiving calls. The antenna diplexer23 is connected to the receiving unit 18 which receives the receptiondata introduced from the antenna 16, performs demodulation-process onthe image and audio or the like and outputs demodulated image and audiodata Din to the CPU 32 or the like. The receiving unit 18 is connectedthrough the CPU 32 to the image-and-audio-processing unit 44 whichdigital-analog-converts digital audio data to output an audio signalSout or digital-analog-converting digital image data to output an imagesignal Sv.

The image-and-audio-processing unit 44 is connected to the speaker 36 afor constituting a big sound use and the speaker 36 b with actuatorfunction for constituting a receiver. The speaker 36 a outputs sounds ofa receiving sound, an incoming melody and the like based on a soundsignal Sout 1 when receiving calls.

Also, the speaker 36 b constitutes a vibration body and vibratestogether with the touch-sensitive variable sheet unit 103 whenrepresenting the sense of touch or in a single manner based on thevibration generation signal Sout2. The speaker 36 b gives the vibrationto the operation surface of the display unit 29 based on the positiondetection signal S1 obtained from the input detection unit 45. It isneedless to say that the speaker 36 b receives an audio signal Sout3 andamplifies the partner's voice or the like.

To the image-and-audio-processing unit 44, a microphone 13 constitutinga telephone transmitter is connected, other than the speakers 36 a, 36b, and outputs an audio signal Sin by collecting the operator's voice 30d. When transmitting calls, the image-and-audio-processing unit 44outputs digital audio data by analog-to-digital converting the analogaudio signal Sin to be transmitted to the partner and/or outputs digitalimage data by analog-to-digital converting the analog image signal Sv.

The CPU 32 is connected, other than the receiving unit 18, to thetransmitting unit 22 which performs modulation-process on the image andaudio data Dout or the like to be transmitting to the partner andsupplies the modulated transmission data to the antenna 16 through theantenna diplexer 23. The antenna 16 radiates a radio wave supplied fromthe antenna diplexer 23 toward a base station or the like.

To the above-mentioned CPU 32, other than the transmitting unit 22, thecamera 34 is connected which shoots a subject and transmits, forexample, still image information or operation information to the partnerthrough the transmitting unit 22. The camera 34 is provided on the rearsurface side of housing. The power supply unit 33 includes a battery 94which supplies a DC power to the receiving unit 18, the transmittingunit 22, the display unit 29, the CPU 32, the camera 34, the memory unit35, the storage unit 37, the image-and-audio-processing unit 44, theinput detection unit 45 and the touch-sensitive variable sheet unit 103.It should be noted that although, in this embodiment, a case in whichthe storage unit 37 is provided separately from theimage-and-audio-processing unit 44 has been described, a memory devicewhich is included in the image-and-audio-processing unit 44 may beconcurrently used. This enables the number of the parts to be reduced.

The following will describe a function example of the input detectionunit 45. FIGS. 21A to 21E and FIGS. 22A to 22E show slide and pressoperation examples (No. 1 and No. 2 thereof) in the mobile phone 600.FIG. 21A and FIG. 22A show operation examples of the operator's finger30 a. FIG. 21B and FIG. 22B show position detection examples obtainedfrom the input detection unit 45. FIG. 21C and FIG. 22C show pressdetection examples obtained from the input detection unit 45. FIG. 21Dand FIG. 22D show driving examples of the piezoelectric unit 315 of theair-circulation unit 3. FIG. 21E and FIG. 22E show reactive forceexamples that are given to the operator's finger 30 a. Each showstransition from a state-I to a state-XI.

In this embodiment, it is assumed that the piezoelectric unit 315 of theair-circulation unit 3 of the touch-sensitive variable sheet unit 103supplies the air to the element bag portions E1 to E25 which swell.Also, the element bag portion E1 shown in FIG. 21A indicates thesense-of-touch-representing unit for representing the sense of touchgenerated on the display region of, for example, the key K1 of numeral“1” in the touch-sensitive variable sheet unit 103. In this element bagportion E1, a x1 indicates a position in the X-axis direction in the XYZcoordinates system and is a position of a protrusion edge portion of theleft side of the element bag portion E1 in FIG. 21A, a x2 indicates aposition of the protrusion center portion thereof and a x3 indicates aposition of a protrusion edge portion of the right side thereof.

By setting these as the input detection condition, the state-I shown inFIG. 21A is a case in which the operator's finger 30 a does not touchthe element bag portion E1 of the touch-sensitive variable sheet unit103. In this case, according to the position detection example shown inFIG. 21B, the position detection signal S1 is not outputted from theinput detection unit 45. Also, according to the press detection exampleshown in FIG. 21C, the press detection signal S2 is not obtained fromthe input detection unit 45. According to the driving example of thepiezoelectric unit 315 shown in FIG. 21D, it is a state in which the airis supplied to the twenty five element bag portions E1 to E25 whichswell in order to present the concave and convex touch feeling.According to the reactive force example given to the operator's finger30 a shown in FIG. 21E, the finger 30 a does not touch the element bagportion E1, so that the reactive force does not occur.

The state-II shown in FIG. 21A is a case in which the operator's finger30 a is slid and operated (sliding) on the touch-sensitive variablesheet unit 103. In this case, according to the position detectionexample shown in FIG. 21B, the position detection by the input detectionunit 45 is continued and some of the position detection signal S1 isoutputted. Also, according to the press detection example shown in FIG.21C, the press detection by the input detection unit 45 is continued,but the pressing force F exceeding the judgment threshold has not yetdetected. According to the driving example of the piezoelectric unit 315shown in FIG. 21D, a state is maintained in which the air is supplied tothe twenty five element bag portions E1 to E25 which swell in order topresent the concave and convex touch feeling. According to the reactiveforce example given to the operator's finger 30 a shown in FIG. 21E, thefinger 30 a touches the touch-sensitive variable sheet unit 103, but theelement bag portion E1 is not pressed, so that the reactive force doesnot occur.

The state-IV shown in FIG. 21A is a case in which the operator's finger30 a is slid and operated (sliding) on the touch-sensitive variablesheet unit 103 and thereafter, reaches to the protrusion edge portion ofthe left side of the element bag portion E1. In this case, according tothe position detection example shown in FIG. 21B, the position detectionsignal S1 showing the position x1 of the protrusion edge portion of theleft side of the element bag portion E1 is outputted from the inputdetection unit 45. Also, according to the press detection example shownin FIG. 21C, the press detection by the input detection unit 45 iscontinued, but the pressing force F exceeding the judgment threshold hasnot yet detected. According to the driving example of the piezoelectricunit 315 shown in FIG. 21D, it is a state in which the air is furthersupplied to the twenty five element bag portions E1 to E25 which furtherswell in order to present the concave and convex touch feeling.According to the reactive force example given to the operator's finger30 a shown in FIG. 21E, the finger 30 a touches the touch-sensitivevariable sheet unit 103 but does not press it, so that the reactiveforce does not occur.

The state-V shown in FIG. 21A is a case in which the operator's finger30 a reaches to the protrusion center portion of the element bag portionE1 of the touch-sensitive variable sheet unit 103. In this case,according to the position detection example shown in FIG. 21B, theposition detection signal S1 showing the position x2 of the protrusioncenter portion of the element bag portion E1 is outputted from the inputdetection unit 45. Also, according to the press detection example shownin FIG. 21C, the press detection by the input detection unit 45 iscontinued, but the pressing force F exceeding the judgment threshold hasnot yet detected. According to the driving example of the piezoelectricunit 315 shown in FIG. 21D, a state is maintained in which the air issupplied to the twenty five element bag portions E1 to E25 which swellstill further in order to present the concave and convex touch feeling.According to the reactive force example given to the operator's finger30 a shown in FIG. 21E, the finger 30 a touches the protrusion centerportion and the operator's finger 30 a obtains the reactive force as theconcave and convex touch feeling by a fact that the element bag portionE1 swells still further.

The state-VI shown in FIG. 21A is a case in which the operator's finger30 a is shifted to the protrusion edge portion of the right side fromthe protrusion center portion of the element bag portion E1 of thetouch-sensitive variable sheet unit 103. In this case, according to theposition detection example shown in FIG. 21B, the position detectionsignal S1 showing the position x3 of the protrusion edge portion of theright side of the element bag portion E1 is outputted from the inputdetection unit 45. Also, according to the press detection example shownin FIG. 21C, the press detection by the input detection unit 45 iscontinued, but the pressing force F exceeding the judgment threshold hasnot yet detected.

According to the driving example of the piezoelectric unit 315 shown inFIG. 21D, the state in which the air is supplied to the twenty fiveelement bag portions E1 to E25 which swell still further returns to thestate of the normal time in which the air is supplied in order topresent the concave and convex touch feeling. In this embodiment, theoperator's finger 30 a will return to the protrusion center portion fromthe protrusion edge portion of the right side of the element bag portionE1 of the touch-sensitive variable sheet unit 103. According to thereactive force example given to the operator's finger 30 a shown in FIG.21E, the finger 30 a touches the protrusion edge portion of the rightside from the protrusion center portion and the operator's finger 30 aobtains the reactive force which is weaker than the state V shown inFIG. 21A as the concave and convex touch feeling by a fact that theelement bag portion E1 swells still further.

The state-VII shown in FIG. 22A is a case in which the operator's finger30 a returns to the protrusion center portion of the element bag portionE1 of the touch-sensitive variable sheet unit 103. In this case,according to the position detection example shown in FIG. 22B, theposition detection signal S1 showing the position x2 of the protrusioncenter portion of the element bag portion E1 is outputted from the inputdetection unit 45. Also, according to the press detection example shownin FIG. 22C, the press detection by the input detection unit 45 iscontinued but the pressing force F exceeding the judgment threshold hasnot yet detected.

According to the driving example of the piezoelectric unit 315 shown inFIG. 22D, a state is maintained in which the air is supplied to thetwenty five element bag portions E1 to E25 which swell still further inorder to present the concave and convex touch feeling. According to thereactive force example given to the operator's finger 30 a shown in FIG.22E, the finger 30 a touches the protrusion center portion and obtainsthe reactive force thereof as the concave and convex touch feeling by afact that the element bag portion E1 swells still further.

The state-VIII shown in FIG. 22A is a case in which the operator'sfinger 30 a starts the press operation at the protrusion center portionof the element bag portion E1 of the touch-sensitive variable sheet unit103. In this case, according to the position detection example shown inFIG. 22B, the operator's finger 30 a stays at the protrusion centerportion of the element bag portion E1, so that the position detectionsignal S1 is not outputted from the input detection unit 45. Also,according to the press detection example shown in FIG. 22C, the pressdetection by the input detection unit 45 is continued but the pressingforce F exceeding the judgment threshold has not yet detected.

According to the driving example of the piezoelectric unit 315 shown inFIG. 22D, it is a state in which the air is supplied to the twenty fiveelement bag portions E1 to E25 which start swelling still further inorder to overcome the pressing force F by the press operation of theoperator's finger 30 a. According to the reactive force example given tothe operator's finger 30 a shown in FIG. 22E, the finger 30 a pressesthe protrusion center portion toward the Z-direction and obtains thereactive force as the concave and convex touch feeling by a fact thatthe element bag portion E1 swells still further.

The state-IX shown in FIG. 21A is a case just before the operator'sfinger 30 a completes pressing the protrusion center portion of theelement bag portion E1 of the touch-sensitive variable sheet unit 103.In this case, according to the position detection example shown in FIG.22B, the operator's finger 30 a stays at the protrusion center portionof the element bag portion E1, so that the position detection signal S1is not outputted from the input detection unit 45. Also, according tothe press detection example shown in FIG. 22C, the input detection unit45 detects the press detection signal S2 showing the pressing force Fexceeding the judgment threshold.

According to the driving example of the piezoelectric unit 315 shown inFIG. 22D, a state is maintained in which the air is supplied to thetwenty five element bag portions E1 to E25 which swell still further inorder to overcome the pressing force F by the press operation of theoperator's finger 30 a. According to the reactive force example given tothe operator's finger 30 a shown in FIG. 22E, the finger 30 a pressesthe protrusion center portion toward the Z-direction and obtains thereactive force as the concave and convex touch feeling by a fact thatthe element bag portion E1 swells further.

The state-X shown in FIG. 22A is a case in which the pressing force F isgradually decreased after the operator's finger 30 a completes pressingthe protrusion center portion of the element bag portion E1 of thetouch-sensitive variable sheet unit 103. In this case, according to theposition detection example shown in FIG. 22B, the operator's finger 30 astays at the protrusion center portion of the element bag portion E1, sothat the position detection signal S1 is not outputted from the inputdetection unit 45. Also, according to the press detection example shownin FIG. 22C, the input detection unit 45 detects the press detectionsignal S2 showing the pressing force F which is less than the judgmentthreshold and is decreasing gradually.

According to the driving example of the piezoelectric unit 315 shown inFIG. 22D, a state is continued in which the air is supplied to thetwenty five element bag portions E1 to E25 which swell still further inorder to overcome the pressing force F by the press operation of theoperator's finger 30 a. According to the reactive force example given tothe operator's finger 30 a shown in FIG. 22E, the finger 30 a pressesthe protrusion center portion little by little in the Z-direction andthe element bag portion E1 is gradually shifted to the normal swelling,so that the finger 30 a obtains the concave and convex touch feeling inwhich the reactive force is gradually decreased.

In this manner, the output [pa] of the piezoelectric unit 315 iscontrolled by making the position detection signal S1 and the pressdetection signal S2 as the triggers, so that it becomes possible torepresent the more real and local concave and convex touch feeling.

The following will describe an information processing example of themobile phone 600. FIG. 23 shows a control example of a display unit anda touch-sensitive variable sheet unit in the mobile phone 600 at a timeof execution of application.

In this example, there is cited a case in which, based on the selectionof the application #A or #B, the mobile phone 600 mounted with the inputdevice 300 displays either of the operation screens shown in FIGS. 19Aand 19B and, by linking with this display, thesense-of-touch-representing unit is built by sending the air to theelement bag portions E1 to E17 (first group) or the element bag portionsE18 to E25 (second group) in the touch-sensitive variable sheet unit 103(hereinafter, referred to as operation panel building mode). In thisexample, a case is illustrated in which a selection candidate is changedover in order of the application #A and the application #B with respectto the operation panel building mode base on an application executioninstruction.

By setting these as the operation panel changeover condition, the CPU 32inputs an application execution instruction at step ST1 of the flowchartshown in FIG. 23. The application execution instruction is given to theCPU 32, for example, by making power switch-ON information as a trigger.Thereafter, the process shifts to step ST2 where the CPU 32 branches thecontrol thereof depending on whether the application executioninstruction is an execution instruction of the application #A or anexecution instruction of the other application. If the applicationexecution instruction is an execution instruction of the application #A,then the process shifts to step ST3 where the CPU 32 reads controlinformation of the application #A. The control information is madecorrespondence with the application #A, the application #B or the likebeforehand. The CPU 32 controls the display unit 29 so as to change overthe display thereof based on the control information.

At that time, the CPU 32 outputs an image signal Sv to the display unit29 based on the control information. The display unit 29, based on theimage signal Sv, displays the icon images of the key K1 of numeral “1”to the key K10 of numeral “0”, the key K11 of symbol “*”, the key K12 ofsymbol “#” or the like, the key K13 of determination “O” of the crosskey, the left facing arrow key K14 thereof, the upward facing arrow keyK15 thereof, the right facing arrow key K16 thereof and the downwardfacing arrow key K17 thereof, which form the icon images of the firstgroup (referred to as FIG. 19A).

Also, the CPU 32 outputs the instruction data D based on the controlinformation to the air-circulation unit 3 of the touch-sensitivevariable sheet unit 103. The air-circulation unit 3 executes achangeover control so as to open the valve body 304 and to shut off thevalve body 305 based on the instruction data D in order to select theflow channel 2 a. The blower 3 b sends the air to the flow channel 2 aselected by the flow channel changeover unit 3 a. The piezoelectric unit315 constituting the blower 3 b adjusts an amount of the air. Thepiezoelectric unit 315 is controlled by the instruction data D inputtedfrom the CPU 32. This control enables the concave and convex touchfeeling of the seventeen element bag portions E1 to E17 of the firstgroup to change.

In this example, the display region of the key K1 of numeral “1”corresponds to the element bag portion E1 shown in FIG. 18, andsimilarly, the display region of the key K2 of numeral “2” correspondsto the element bag portion E2 shown in FIG. 18. The display region ofthe key K3 of numeral “3” corresponds to the element bag portion E3shown in FIG. 18. The display region of the key K4 of numeral “4”corresponds to the element bag portion E4 shown in FIG. 18. The displayregion of the key K5 of numeral “5” corresponds to the element bagportion E5 shown in FIG. 18. The display region of the key K6 of numeral“6” corresponds to the element bag portion E6 shown in FIG. 18. Thedisplay region of the key K7 of numeral “7” corresponds to the elementbag portion E7 shown in FIG. 18. The display region of the key K8 ofnumeral “8” corresponds to the element bag portion E8 shown in FIG. 18.The display region of the key K9 of numeral “9” corresponds to theelement bag portion E9 shown in FIG. 18. The display region of the keyK10 of numeral “0” corresponds to the element bag portion E10 shown inFIG. 18. The respective display regions enable the concave and convextouch feeling to be given to the operator's finger when the slideoperation or the press operation is executed.

Further, the display region of the key K11 of symbol “*” corresponds tothe element bag portion E11 shown in FIG. 18 and the display region ofthe key K12 of symbol “#” corresponds to the element bag portion E12.The respective display regions enable the concave and convex touchfeeling to be given to the operator's finger. Similarly, the displayregion of the key K13 of determination “O” which forms the cross keycorresponds to the element bag portion E13, the display region of theleft facing arrow key K14 thereof corresponds to the element bag portionE14 and the display region of the upward facing arrow key K15 thereofcorresponds to the element bag portion E15. Further, the display regionof the right facing arrow key K16 thereof corresponds to the element bagportion E16 and the display region of the downward facing arrow key K17thereof corresponds to the element bag portion E17. When the slideoperation or the press operation is executed, the respective displayregions enable the concave and convex touch feeling to be given to theoperator's finger.

Then, the CPU 32 executes the application #A at step ST4. Theapplication #A is such a processing for inputting the information byoperating, for example, the key K1 of numeral “1” to the key K10 ofnumeral “0”, the key K11 of symbol “*”, the key K12 of symbol “#” or thelike, the key K13 of determination “O” of the cross key, the left facingarrow key K14 thereof, the upward facing arrow key K15 thereof, theright facing arrow key K16 thereof or the downward facing arrow key K17thereof.

Thereafter, the process shifts to step ST5 where the CPU 32 judges anend of the application #A. If there is no end-instruction of theapplication #A, the process returns to the step ST4 where the displayunit 29 continues the display of an operation panel image relating tothe application #A. If there is the end-instruction of the application#A, the process shifts to step ST6 where the CPU 32 transmits theinstruction data D to the air-circulation unit 3 so as to controlstopping the piezoelectric unit 315. At this time point, the display ofthe operation panel image relating to the application #A may be changedto, for example, a menu screen or the like. Thereafter, the processshifts to step ST13.

If the application execution instruction other than the executioninstruction of the application #A is set at the above-mentioned stepST2, the process shifts to step ST7. At the step ST7, the CPU 32branches the control thereof depending on whether the applicationexecution instruction is an execution instruction of the application #Bor an execution instruction of the other application. If the applicationexecution instruction is the application #B, the process shifts to stepST8 where the CPU 32 reads the control information of the application#B. The CPU 32 controls the display unit 29 so as to change over thedisplay based on the control information.

At that time, the CPU 32 outputs an image signal Sv based on the controlinformation to the display unit 29. On the display unit 29, there aredisplayed the icon images of the key K18 of “etc”, the key K19 of “REW”,the left facing arrow stop key K20, the right facing arrow stop key K21,the left facing fast-forward key K22, the fast-forward key K23, thereproduction key K24 and the stop key K25, which form the icon images ofthe second group, and at the same time, the video of the reproductionapplication or the like (referred to as FIG. 19B).

Also, the CPU 32 outputs the instruction data D based on the controlinformation to the air-circulation unit 3. The air-circulation unit 3executes a changeover control so as to open the valve body 305 and toshut off the valve body 304 based on the instruction data D in order toselect the flow channel 2 b. The blower 3 b sends the air to the flowchannel 2 b selected by the flow channel changeover unit 3 a. Thepiezoelectric unit 315 constituting the blower 3 b adjusts an amount ofthe air. The piezoelectric unit 315 is controlled by the instructiondata D inputted from the CPU 32. This control enables the concave andconvex touch feeling of the eight element bag portions E18 to E25 of thesecond group to be changed.

In this embodiment, the display region of the key K18 of “etc”corresponds to the element bag portion E18 shown in FIG. 18 andsimilarly, the display region of the key K19 of “REW” corresponds to theelement bag portion E19. The display region of the left facing arrowstop key K20 corresponds to the element bag portion E20, the displayregion of the right facing arrow stop key K21 corresponds to the elementbag portion E21 and the display region of the left facing fast-forwardkey K22 corresponds to the element bag portion E22. Further, the displayregion of the fast-forward key K23 corresponds to the element bagportion E23, the display region of the reproduction key K24 correspondsto the element bag portion E24, and the display region of the stop keyK25 corresponds to the element bag portion E25. When the slide operationor the press operation is executed, the respective display regionsenable the concave and convex touch feeling to be given to theoperator's finger.

Then, the CPU 32 executes the application #B at step ST9. Theapplication #B is the processing for reproducing video information byoperating, for example, the key K18 of “etc”, the key K19 of “REW”, theleft facing arrow stop key K20, the right facing arrow stop key K21, theleft facing fast-forward key K22, the fast-forward key K23, thereproduction key K24 or the stop key K25.

Thereafter, the process shifts to step ST10 where the CPU 32 judges anend of the application #B. If there is no end-instruction of theapplication #B, the process returns to the step ST9 where the displayunit 29 continues the operation panel display relating to theapplication #B. If there is the end instruction of the application #B,the process shifts to step ST11 where the CPU 32 transmits theinstruction data D to the air-circulation unit 3 so as to controlstopping the piezoelectric unit 315. Thereafter, the process shifts tostep ST13.

It should be noted that if the application execution instruction otherthan the applications #A and #B is set at the step ST7, then the processshifts to step ST12. The other application is executed at the step ST12.In the processing in this other application, for example, a waitingimage or the like is displayed on the display unit 29 by changing overthe display screen. Also, the air-circulation unit 3 does not select anyof the flow channels 2 a and 2 b, so that the changeover control forshutting off the valve body 304 and the valve body 305 is executed basedon the instruction data D. The piezoelectric unit 315 stops the drivingthereof based on the instruction data D inputted from the CPU 32. Thiscontrol enables any of the twenty five element bag portions E1 to E25 ofthe first and second groups to lose the concave and convex touchfeeling.

Thereafter, the process shifts to step ST13 where the end of the inputprocessing in the mobile phone 600 is judged. For example, the CPU 32detects power-OFF information. If the power-OFF information is notdetected, the process returns to the step ST1 where the above-mentionedprocessing is repeated. If the power-OFF information is detected, theinput processing in the mobile phone 600 ends.

In this manner, the mobile phone 600 as the third embodiment is providedwith the embodiment of the input device 300 so that it becomes possibleto provide a structure in which the convex and concave shape or thepressure changes on the operation screen corresponding to theapplications #A and #B with respect to the slide operation or the pressoperation of the user's finger. Consequently, the operation panelbuilding mode (icon image+sense-of-touch-representing unit) can beexecuted by the sense of touch representation function depending on thetouch-sensitive variable sheet unit 103 and by the display function ofthe icon image of the display unit 29, so that it becomes possible toprovide the mobile phone 600 with the programmable touch-sensitivevariable sheet function for the icon touch. Moreover, it is possible toimprove miniaturization and operability of the input device 300, therebyenabling the reduction of the miss-operation, the cost down and thesimplification of the manufacturing process of the mobile phone 600 tobe realized.

Although, in this embodiment, a case of the touch-sensitive variablesheet unit 103 having the twenty five element bag portions E1 to E25 hasbeen described with respect to the touch-sensitive sheet member, it isnot limited to this; the touch-sensitive variable sheet unit havingtwenty five apertures p1 to p25 for presenting a sense of touch atpredetermined positions of the base member 1 may be constituted. Then,even if the sense of touch given to the operator's finger 30 a ischanged by sending the air to these apertures p1 to p24 from the blower3 b, by feed-back controlling this blower 3 b by the piezoelectric unit315 and the CPU 32, and by adjusting an amount of the air blown out ofthe aperture p1 to p24, the similar effect can be obtained.

Embodiment 4

FIG. 24 shows a configuration of an input device 400 as a fourthembodiment, to which an embodiment of a touch-sensitive sheet member isapplied. In this embodiment, an input device 400 is provided in whichthe element bag portion is arranged by dividing it into three layerseach forming the icon images of one of respective three groups indifferent planes on the display unit 29, which is different from thethird embodiment, and it is possible to execute the operation panelbuilding mode which can select the element bag portions of the groupcorresponding to the icon images from the above-mentioned three groups.

The input device 400 shown in FIG. 24 is a device for inputtinginformation by the slide and/or the pushdown operation depending on thefinger or the like of the operator 30 (operation body). The input device400 contains a display unit 29, an input detection unit 45 and atransparent layered sheet unit 140 by which a sense of touch is changed.These units are layered in this order. Particularly, the input detectionunit 45 and the layered sheet unit 140 are provided on the display unit29.

The layered sheet unit 140 constitutes the touch-sensitive sheet member.In the layered sheet unit 140, a touch-sensitive variable sheet unit 141of a first layer, a touch-sensitive variable sheet unit 142 of a secondlayer and a touch-sensitive variable sheet unit 143 of a third layer arelayered in this order from the downward. The bag structure of theembodiment of the touch-sensitive sheet member 200 is applied to thelayered sheet unit 140.

The display unit 29 displays a plurality of push button switch imagesfor the first to third layers respectively at a time of the inputoperation. The contents of the push button switch images constitute theicon images for the input operation. A key array K100 for a key board orthe like is displayed on the display unit 29 as the push button switchimage for the first layer. In this embodiment, the icon images aredisplayed corresponding to the arrangement of the key array includingthe characters of the numerals, the alphabet and the like in which theoperation keys are lined up in five lines toward the backward from thejust front.

The push button switch image for the second layer includes twenty keysK41 to K60 or the like for various kinds of function selections. Theicon images of, for example, the Internet, a calendar, a camera, acalculator, a music, a telephone, a multimedia, user data, an album,various kinds of settings, a timer, a television, a Web, a wake-up calland the like are displayed on the display unit 29.

The push button switch image for the third layer includes the iconimages of the key K1 of numeral “1” to the key K10 of numeral “0”, thekey K11 of symbol “*”, the K12 of symbol “#” or the like, the key K13 ofdetermination “O” constituting the cross key, the left facing arrow keyK14 thereof, the upward facing arrow key K15 thereof, the right facingarrow key K16 thereof, the downward facing arrow key K17 thereof or thelike, which is similarly as the third embodiment and are displayed onthe display unit 29. As the display unit 29, a liquid crystal displaydevice (LCD device) is used.

Similarly as the third embodiment, the input detection unit 45 isprovided on the upper portion of the display unit 29 and operates so asto detect the slide position and pressing force of the operator's fingeror the like. For the input detection unit 45, as explained in the thirdembodiment, an input device having a constitution which can give theposition detection information and the press detection information to acontrol system is used. For example, a capacitive touch panel, aresistive touch panel, an input device of surface acoustic wave system(SAW) or optical system, or multi-stage system tact switch or the likeis used.

The transparent touch-sensitive variable sheet unit 141 for the firstlayer is provided on the upper portion of the input detection unit 45.The touch-sensitive variable sheet unit 141 is provided so as to coverthe whole of the input detection unit 45 and is pushed-down and operatedalong the operation surface of the display unit 29. In this embodiment,the touch-sensitive variable sheet unit 141 has a substrate 2 c and atthe upper portion thereof, a base member 104 having predeterminedhardness and a plurality of rectangular dish shaped concave portions(hereinafter, referred to as element bag portion array E100) and aplurality of flow channels 2 d to 2 h. In this embodiment, the elementbag portion array E100 is arranged corresponding to the arrangement ofthe key array (including the characters of the numerals, the alphabetand the like) in which the operation keys are lined up in five linestoward the backward from the just front.

In the base member 104, for example, a flow channel 2 d is arrangedcorresponding to the operation keys of the first line. A flow channel 2e is arranged corresponding to the operation keys of the second line. Aflow channel 2 f is arranged corresponding to the operation keys of thethird line. A flow channel 2 g is arranged corresponding to theoperation keys of the fourth line. A flow channel 2 h is arrangedcorresponding to the operation keys of the fifth line. It is needless tosay that the touch-sensitive variable sheet unit 141 may cover a portionof the input detection unit 45. In this embodiment, the upper portion ofthe base member 104 is sealed in (covered) by the substrate 2 c, whichbecomes a lid, of the touch-sensitive variable sheet unit 142 of thesecond layer on the rear surface side thereof in order to improve theair-tightness. In this manner, the element bag portion array E100 isconstituted of the base member 104 and the substrate 2 c of thetouch-sensitive variable sheet unit 142.

On the upper portion of the above-mentioned touch-sensitive variablesheet unit 141, the touch-sensitive variable sheet unit 142 is arranged.The touch-sensitive variable sheet unit 142 includes a substrate 2 c andon the upper portion thereof, a base member 105 having predeterminedhardness and twenty rectangular dish shaped element bag portions E41 toE60 and a flow channel 2 i. In this embodiment, the element bag portionsE41 to E60 are arranged at positions corresponding to the icon images ofthe Internet, the calendar, the camera, the calculator, the music, thetelephone, the multimedia, the user data, the album, various kinds ofthe settings, the timer, the television, the Web, the wake-up call andthe like. The upper portion of this base member 105 is also sealed in bythe substrate 2 c, which becomes a lid, of the touch-sensitive variablesheet unit 143 of the second layer on the rear surface side thereof inorder to improve the air-tightness. In this manner, the element bagportions E41 to E60 are constituted of the base member 105 and thesubstrate 2 c of the touch-sensitive variable sheet unit 143.

On the upper portion of the above-mentioned touch-sensitive variablesheet unit 142, the touch-sensitive variable sheet unit 143 is arranged.The touch-sensitive variable sheet unit 143 includes a substrate 2 cthereof and the upper portion thereof, a base member 106 havingpredetermined hardness and seventeen elliptical dish shaped element bagportions E1 to E17 and a flow channel 2 a. In this embodiment, theelement bag portions E1 to E12 are arranged at positions correspondingto the icon images of the keys of numeral “0” to numeral “9”, the keysof symbol “*”, symbol “#” and the like, and the element bag portions E13to E17 are arranged at positions corresponding to the icon images of thecross key and the like.

In this embodiment, the upper portion of the base member 106 is sealedin (covered) by a film portion 5 for a sheet shaped lid in order toimprove the air-tightness. As the film portion 5, there is used atransparent material with transmissivity and a refractive index which isapproximately equal to the transmissivity and refractive index of thebase member 101. For example, a zeonor (trademark) of the film thicknessof around 25 [μm] is used. The hardness thereof is around 20° to 40°. Inthis manner, the seventeen element bag portions E1 to E17 areconstituted of the base member 106 and the film portion 5.

An air-circulation unit 3A as shown in FIG. 25A is connected to theabove-mentioned seven flow channels 2 a, 2 d to 2 i of the three layeredtouch-sensitive variable sheet units 141 to 143. FIGS. 25A and 25B showan air supply example in the input device 400. The input device 400shown in FIG. 25A includes the display unit 29, the input detection unit45, the layered sheet unit 140 and the air-circulation unit 3A. Theair-circulation unit 3A operates so as to send air to the flow channels2 d to 2 h of the touch-sensitive variable sheet unit 141 of the firstlayer, the flow channel 2 i of the touch-sensitive variable sheet unit142 of the second layer or the flow channel 2 a of the touch-sensitivevariable sheet unit 143 of the third layer. In this embodiment, theair-circulation unit 3A has a programmable function for sending the airto the three layered touch-sensitive variable sheet units 141 to 143,for every layer, which constitute the layered sheet unit 140. Also inthis embodiment, for the air-circulation unit 3A, the blower 3 b (airpressure generator) using a piezoelectric device is used.

FIG. 25B is a plan view of the touch-sensitive variable sheet unit 142of the second layer of the input device 400 and a valve changeover unit308 for the second layer in a flow channel changeover unit 3A forshowing configurations thereof. The air-circulation unit 3A shown inFIG. 25B includes the flow channel changeover unit 3 a 1 and the blower3 b. The blower 3 b having the piezoelectric unit 315 is used. Theblower 3 b is connected to the seven flow channels 2 a, 2 d to 2 ithrough the flow channel changeover unit 3 a 1 as shown in FIG. 25B.

The blower 3 b sends compressed air to the element bag portion arrayE100 of the touch-sensitive variable sheet unit 141 through the flowchannel changeover unit 3 a 1 and the five flow channels 2 d to 2 h,sends compressed air to the twenty element bag portions E41 to E60 ofthe touch-sensitive variable sheet unit 142 through the flow channelchangeover unit 3 a 1 and the flow channel 2 i and sends compressed airto the seventeen element bag portions E1 to E17 of the touch-sensitivevariable sheet unit 143 through the flow channel changeover unit 3 a 1and the flow channel 2 a.

The flow channel changeover unit 3 a 1 includes a valve core portion301A, valve changeover units 302, 308, 319, valve bodies 304, 309, 322and the like. The valve core portion 301A has, for example, arectangular sectional shape and is composed of a core member in which aresin or a light metal is molded by a die.

The valve changeover units 302, 308, 319 each having a fan shape areprovided in the valve core portion 301A. An air-intake tube 324 whichcommunicates to the blower 3 b is provided on the valve changeover units302, 308, 319 and takes air therein from the blower 3 b. The valvechangeover unit 302 contains the valve body 304 and the air-exhaust port306. The valve body 304 operates so as to shut off or so as to open theair-exhaust port 306 by obtaining the drive-power of the driving unit 3c 1 of a motor, a solenoid or the like. The air-exhaust port 306communicates to the flow channel 2 a. The driving unit 3 c 1 isprovided, for example, on the rear surface side of the valve coreportion 301A.

The valve changeover unit 308 contains the valve body 309 and anair-exhaust port 310. The valve body 309 operates so as to shut off orso as to open the air-exhaust port 310 by obtaining the drive-power ofthe driving unit 3 c 1. The air-exhaust port 310 communicates to theflow channel 2 i.

The valve changeover unit 319 contains the valve body 322 and anair-exhaust port 323. The valve body 322 operates so as to shut off orso as to open the air-exhaust port 323 by obtaining the drive-power ofthe driving unit 3 c 1. The air-exhaust port 323 communicates to theflow channels 2 d to 2 h. As each of the valve bodies 304, 309, 322, aplate rubber sheet member having a long oval shape is used. It should benoted that members having the same name and numeral as those of thefirst embodiment have the same functions as those of the firstembodiment, so that the explanation thereof will be omitted.

In the embodiment, when the valve body 304 is opened through the drivingunit 3 c, the air supplied from the blower 3 b is introduced to theseventeen element bag portions E1 to E17 of the touch-sensitive variablesheet unit 143 by passing through the air-exhaust port 306 and the flowchannel 2 a.

When the valve body 309 is opened, the air supplied from the blower 3 bis introduced to the twenty pieces of the element bag portions E41 toE52 (referred to as FIG. 24) and the element bag portions E53 to E60 ofthe touch-sensitive variable sheet unit 142 by passing through theair-exhaust port 310 and the flow channel 2 i. Further, when the valvebody 322 is opened, the air supplied from the blower 3 b is introducedto the element bag portion array E100 (referred to as FIG. 24) and theelement bag portions E53 to E60 of the touch-sensitive variable sheetunit 141 by passing through the air-exhaust port 323 and the flowchannels 2 d to 2 h. It should be noted that when the valve bodies 304,309, 322 are shut off at the same time, the air supply to all of theelement bag portions E1 to E17, the element bag portions E41 to E60 andthe element bag portion array E100 of the layered sheet unit 140 stops.

Accordingly, it is possible to constitute the programmableair-circulation unit 3A for sending the air to the flow channels 2 d to2 h of the touch-sensitive variable sheet unit 141 of the first layer,the flow channel 2 i of the touch-sensitive variable sheet unit 142 ofthe second layer or the flow channel 2 a of the touch-sensitive variablesheet unit 143 of the third layer. This enables the element bag portionsE1 to E17, the element bag portions E41 to E60 or the element bagportion array E100 and the like to be filled up with the air suppliedfrom the air-circulation unit 3A by passing through the flow channels 2a, 2 d to 2 i in the input device 400 shown in FIG. 24.

FIGS. 26A to 26C show display examples of operation panel images inmobile phones 710, in each of which the input device 400 is mounted. Themobile phone 710 shown in FIG. 26A is used in the vertically wide mannerand according to the mobile phone 710, the key K1 of numeral “1” to thekey K10 of numeral “0”, the key K11 of symbol “*”, the key K12 of symbol“#” or the like, the key K13 of determination “O” of the cross key, theleft facing arrow key K14 thereof, the upward facing arrow key K15thereof, the right facing arrow key K16 thereof, the downward facingarrow key K17 thereof, which form the icon images of the application #1,are displayed as the operation screen on the display unit 29 includingthe operation surface.

In this embodiment, the display region of the key K1 of numeral “1”corresponds to the element bag portion E1 shown in FIG. 24, andsimilarly, the display region of the key K2 of numeral “2” correspondsto the element bag portion E2 shown in FIG. 24. The display region ofthe key K3 of numeral “3” corresponds to the element bag portion E3shown in FIG. 24. The display region of the key K4 of numeral “4”corresponds to the element bag portion E4 shown in FIG. 24. The displayregion of the key K5 of numeral “5” corresponds to the element bagportion E5 shown in FIG. 24. The display region of the key K6 of numeral“6” corresponds to the element bag portion E6 shown in FIG. 24. Thedisplay region of the key K7 of numeral “7” corresponds to the elementbag portion E7 shown in FIG. 24. The display region of the key K8 ofnumeral “8” corresponds to the element bag portion E8 shown in FIG. 24.The display region of the key K9 of numeral “9” corresponds to theelement bag portion E9 shown in FIG. 24. The display region of the keyK10 of numeral “0” corresponds to the element bag portion E10 shown inFIG. 24. The respective display regions enable the concave and convextouch feeling to be given to the operator's finger when the slideoperation or the press operation is executed.

Further, the display region of the key K11 of symbol “*” corresponds tothe element bag portion E11 shown in FIG. 24 and the display region ofthe key K12 of symbol “#” corresponds to the element bag portion E12.The respective display regions enable the concave and convex touchfeeling to be given to the operator's finger. Similarly, the displayregion of the key K13 of determination “O” which forms the cross keycorresponds to the element bag portion E13, the display region of theleft facing arrow key K14 thereof corresponds to the element bag portionE14 and the display region of the upward facing arrow key K15 thereofcorresponds to the element bag portion E15. Further, the display regionof the right facing arrow key K16 thereof corresponds to the element bagportion E16 and the display region of the downward facing arrow key K17thereof corresponds to the element bag portion E17. When the slideoperation or the press operation is executed, the respective displayregions enable the concave and convex touch feeling to be given to theoperator's finger. The concave and convex touch feeling on the iconimage of such a application #1 occurs based on a fact in which theair-circulation unit 3A is controlled such that the flow channelchangeover unit 3 a 1 shown in FIG. 25B selects the flow channel 2 a tosend the air to the touch-sensitive variable sheet unit 143 having thebase member 106 which is concurrently used as the flow channel panel.

According to the mobile phone 710 shown in FIG. 26B, the key images ofthe Internet, the calendar, the camera, the calculator, the music, thetelephone, the multimedia, the user data, the album, various kinds ofthe settings, the timer, the television, the Web, the wake-up call orthe like, which form the icon images of the application #2, aredisplayed as the operation screen on the display unit 29 including theoperation surface. In this embodiment, the element bag portions E41 toE60 are arranged at positions corresponding to the icon images of theInternet, the calendar, the camera, the computer, the music, thetelephone, the multimedia, the user data, the album, various kinds ofthe settings, the timer, the television, the Web, the wake-up call orthe like. When the slide operation or the press operation is executed,the operator's finger obtains respective concave and convex touchfeelings. The concave and convex touch feeling on the icon image of sucha application #2 occurs based on a fact in which the air-circulationunit 3A is controlled such that the flow channel changeover unit 3 a 1shown in FIG. 25B selects the flow channel 2 i to send the air to thetouch-sensitive variable sheet unit 142 having the base member 105 whichis concurrently used as the flow channel panel.

The mobile phone 710 shown in FIG. 26C is used in the horizontally widemanner, and according to the mobile phone 710, the key array K100 forthe key board which forms the icon images of the application #3 isdisplayed as the operation screen on the display unit 29 including theoperation surface. The image of the key array K100 includes thecharacters of the numerals, the alphabet or the like in which theoperation keys are lined up in five lines toward the backward from thejust front. In this embodiment, the element bag portion array E100 isarranged at the position corresponding to the icon image of the keyarray in which the operation keys for the key board are lined up in fivelines toward the backward from the just front. The respective concaveand convex touch feelings are obtained when the slide operation or thepress operation is executed.

The concave and convex touch feeling on the icon image of such aapplication #3 occurs based on a fact in which the air-circulation unit3A is controlled such that the flow channel changeover unit 3 a 1 shownin FIG. 25B selects the flow channels 2 d to 2 h to send the air to thetouch-sensitive variable sheet unit 141 having the base member 104 whichis concurrently used as the flow channel panel.

In this embodiment, when touch-typing the key array K100 for the keyboard which forms the icon images of the application #3, it is possibleto obtain the sense of touch that the finger 30 a feels. Further, evenwhen the key top that has not a plane surface (for example, such as adome shape) is pushed down, it is possible to obtain the representationof the sense of touch that the finger 30 a feels. Also, it becomespossible to realize the shape representation in which the sense of touchis used on the operation screen and also, the position on the operationkey screen for the sense of touch representation may change depending onthe states of the applications #1 to #3.

The following will describe an information processing example in themobile phone 710. FIG. 27 and FIG. 28 show a control example (Nos. 1 and2) of the display unit and the layered sheet unit 140 for representing asense of touch in the mobile phone 710 at a time of the execution of theapplication.

In this example, there is cited a case in which, based on the selectionof the applications #1 to #3, the mobile phone 710 mounted with theinput device 400 displays any of the operation screens shown in FIGS.26A to 26C and at the same time, by linking with this display, thesense-of-touch-representing unit is built by sending the air to theelement bag portions E1 to E17, the element bag portions E41 to E60 orthe element bag portion array E100 in the touch-sensitive variable sheetunits 141 to 143 (operation panel building mode).

In this example, a case is illustrated in which a selection candidate ischanged over in order of the application #1 the application #2 theapplication #3 with respect to the operation panel building mode basedon an application execution instruction. It is needless to say that theCPU 32 for controlling the layered sheet unit 140 for presenting a senseof touch controls the air-circulation unit 3A so as to supply the air tothe three layered element bag portions E1 to E25 for presenting a senseof touch of the layered sheet unit 140 corresponding to the imagecontents displayed on the display unit 29, and the touch-sensitivevariable sheet units 141 to 143 are available at predetermined positionsof the base members 104, 105, 106 corresponding to the image contents.

By setting these as the operation panel changeover condition, the CPU 32inputs the application execution instruction at step ST21 of theflowchart shown in FIG. 27. The application execution instruction isgiven to the CPU 32, for example, by making power switch-ON informationas a trigger. Thereafter, the process shifts to step ST22 where the CPU32 branches the control thereof depending on whether the applicationexecution instruction is an execution instruction of the application #1or other application execution instruction. If the application executioninstruction is the application #1, the process shifts to step ST23 wherethe CPU 32 reads the control information of the application #1. Thecontrol information is made correspondence with the application #1, theapplication #2, the application #3 or the like beforehand. The CPU 32controls the display unit 29 so as to change over the display thereofbased on the control information.

At that time, the CPU 32 outputs an image signal Sv to the display unit29 based on the control information. The display unit 29, based on theimage signal Sv, displays the icon images of the key K1 of numeral “1”to the key K10 of numeral “0”, the key K11 of symbol “*”, the key K12 ofsymbol “#” or the like, the key K13 of determination “O” of the crosskey, the left facing arrow key K14 thereof, the upward facing arrow keyK15 thereof, the right facing arrow key K16 thereof and the downwardfacing arrow key K17 thereof, which form the icon images of the firstgroup (referred to as FIG. 26A).

Also, the CPU 32 outputs the instruction data D based on the controlinformation to the air-circulation unit 3A of the input device 400. Theair-circulation unit 3A executes a changeover control so as to open thevalve body 304 or so as to shut off the valve bodies 309, 322 based onthe instruction data D in order to select the flow channel 2 a of thetouch-sensitive variable sheet unit 143. The blower 3 b sends the air tothe flow channel 2 a selected by the flow channel changeover unit 3 a 1.The piezoelectric unit 315 constituting the blower 3 b adjusts an amountof the air. The piezoelectric unit 315 is controlled by the instructiondata D inputted from the CPU 32. This control enables the concave andconvex touch feeling of the seventeen element bag portions E1 to E17 ofthe positions corresponding to the icon images of the application #1 tochange.

In this example, the display region of the key K1 of numeral “1”corresponds to the element bag portion E1 shown in FIG. 24, andsimilarly, the display region of the key K2 of numeral “2” correspondsto the element bag portion E2 shown in FIG. 24. The display region ofthe key K3 of numeral “3” corresponds to the element bag portion E3shown in FIG. 24. The display region of the key K4 of numeral “4”corresponds to the element bag portion E4 shown in FIG. 24. The displayregion of the key K5 of numeral “5” corresponds to the element bagportion E5 shown in FIG. 24. The display region of the key K6 of numeral“6” corresponds to the element bag portion E6 shown in FIG. 24. Thedisplay region of the key K7 of numeral “7” corresponds to the elementbag portion E7 shown in FIG. 24. The display region of the key K8 ofnumeral “8” corresponds to the element bag portion E8 shown in FIG. 24.The display region of the key K9 of numeral “9” corresponds to theelement bag portion E9 shown in FIG. 18. The display region of the keyK10 of numeral “0” corresponds to the element bag portion E10 shown inFIG. 24. The respective display regions enable the concave and convextouch feeling to be given to the operator's finger when the slideoperation or the press operation is executed.

Further, the display region of the key K11 of symbol “*” corresponds tothe element bag portion E11 shown in FIG. 24 and the display region ofthe key K12 of symbol “#” corresponds to the element bag portion E12.The respective display regions enable the concave and convex touchfeeling to be given to the operator's finger. Similarly, the displayregion of the key K13 of determination “O” which forms the cross keycorresponds to the element bag portion E13, the display region of theleft facing arrow key K14 thereof corresponds to the element bag portionE14 and the display region of the upward facing arrow key K15 thereofcorresponds to the element bag portion E15. Further, the display regionof the right facing arrow key K16 thereof corresponds to the element bagportion E16 and the display region of the downward facing arrow key K17thereof corresponds to the element bag portion E17. When the slideoperation or the press operation is executed, the respective displayregions enable the concave and convex touch feeling to be given to theoperator's finger.

Then, the CPU 32 executes the application #A at step ST24. Theapplication #A is such a processing for inputting the information byoperating, for example, the key K1 of numeral “1” to the key K10 ofnumeral “0”, the key K11 of symbol “*”, the key K12 of symbol “#” or thelike, the key K13 of determination “O” of the cross key, the left facingarrow key K14 thereof, the upward facing arrow key K15 thereof, theright facing arrow key K16 thereof or the downward facing arrow key K17thereof.

Thereafter, the process shifts to step ST25 where the CPU 32 judges anend of the application #A. If there is no end-instruction of theapplication #A, the process returns to the step ST24 where the displayunit 29 continues the display of an operation panel image relating tothe application #A. If there is the end-instruction of the application#A, the process shifts to step ST26 where the CPU 32 transmits theinstruction data D to the air-circulation unit 3A so as to controlstopping the piezoelectric unit 315. At this time point, the display ofthe operation panel image relating to the application #A may be changedto, for example, a menu screen or the like. Thereafter, the processshifts to step ST38.

If the application execution instruction other than the application #1is set at the above-mentioned step ST22, the process shifts to stepST27. At the step ST27, the CPU 32 branches the control thereofdepending on whether the application execution instruction is anexecution instruction of the application #2 or an execution instructionof other application. If the application execution instruction is anexecution instruction of the application #2, the process shifts to stepST28 where the CPU 32 reads the control information of the application#2. The CPU 32 controls the display unit 29 so as to change over thedisplay based on the control information.

At that time, the CPU 32 outputs an image signal Sv based on the controlinformation to the display unit 29. The display unit 29 displays the keyimages of the Internet, the calendar, the camera, the calculator, themusic, the telephone, the multimedia, the user data, the album, variouskinds of the settings, the timer, the television, the Web, the wake-upcall or the like, which form the icon images of the application #2, asthe operation screen (referred to as FIG. 26B).

Also, the CPU 32 outputs the instruction data D based on the controlinformation to the air-circulation unit 3A. The air-circulation unit 3Aexecutes the changeover control so as to open the valve body 309 or soas to shut off the valve bodies 304, 322 based on the instruction data Din order to select the flow channel 2 i. The blower 3 b sends the air tothe flow channel 2 b selected by the flow channel changeover unit 3 a 1.The piezoelectric unit 315 constituting the blower 3 b adjusts an amountof the air. The piezoelectric unit 315 is controlled by the instructiondata D inputted from the CPU 32. This control enables the concave andconvex touch feeling of the twenty element bag portions E41 to E60corresponding to the icon images of the application #2 to be changed.

Then, the CPU 32 executes the application #2 at step ST29. Theapplication #2 processes the information by operating, for example, thetwenty keys K41 to K60 for various kinds of function selectionoperations corresponding to the icon images of the Internet, thecalendar, the camera, the calculator, the music, the telephone, themultimedia, the user data, the album, various kinds of the settings, thetimer, the television, the Web, the wake-up call and the like. When theslide operation or the press operation is executed, the respectiveconcave and convex touch feelings are obtained.

Thereafter, the process shifts to step ST30 where the CPU 32 judges theend of the application #2. If there is no end-instruction of theapplication #2, the process returns to the step ST29 where the displayunit 29 continues the display of the operation panel images relating tothe application #2. If there is the end-instruction of the application#2, the process shifts to step ST31 where the CPU 32 transmits theinstruction data D to the air-circulation unit 3A so as to controlstopping the piezoelectric unit 315. Thereafter, the process shifts tothe step ST38.

It should be noted that if the application execution instruction otherthan the execution instructions of the applications #1 and #2 is set atthe step ST27, the process shifts to step ST32 shown in FIG. 28. In thestep ST32, if the application execution instruction is an executioninstruction of the application #3, the process shifts to step ST33 wherethe CPU 32 reads the control information of the application #3. The CPU32 controls the display unit 29 so as to change over the display basedon the control information.

At that time, the CPU 32 outputs an image signal Sv to the display unit29 based on the control information. The display unit 29 displays thekey array K100 for the key board which forms the icon image of theapplication #3 as the operation screen (referred to as FIG. 26C). Also,the CPU 32 outputs the instruction data D to the air-circulation unit 3Abased on the control information. The air-circulation unit 3A executesthe changeover control such that the valve body 322 is opened and thevalve bodies 304, 309 are shut off based on the instruction data D inorder to select the flow channels 2 d to 2 h. The blower 3 b sends theair to the flow channels 2 d to 2 h selected by the flow channelchangeover unit 3 a 1. The piezoelectric unit 315 constituting theblower 3 b adjusts an amount of the air. The piezoelectric unit 315 iscontrolled by the instruction data D inputted from the CPU 32. Thiscontrol enables the concave and convex touch feeling of the element bagportion array E100 corresponding to the icon images of the application#3 to be changed.

Then, at step ST34, the CPU 32 executes the application #3. Theapplication #3 processes the information by operating, for example, thekey array K100 for the key board. The key array K100 for the key boardgives the respective concave and convex touch feelings to the operator'sfinger when the slide operation or press operation thereof is executed.

Thereafter, the process shifts to step ST35 where the CPU 32 judges theend of the application #3. If there is no end-instruction of theapplication #3, the process returns to the step ST34 where the displayunit 29 continues the operation panel display relating to theapplication #3. If there is the end-instruction of the application #3,the process shifts to step ST36 where the CPU 32 transmits theinstruction data D to the air-circulation unit 3A so as to controlstopping the piezoelectric unit 315. Thereafter, the process shifts tothe step ST38.

At the above-mentioned step ST32, if an application executioninstruction other than the execution instructions of the applications #1to #3 is set, the process shifts to step ST17 where this application isexecuted. In the processing in this application, for example, a waitingimage or the like is displayed on the display unit 29 by changing overthe display screen. Also, the air-circulation unit 3A performs thechangeover control such that the valve body 304 and the valve bodies309, 322 are shut off based on the instruction data D in order not toselect any of the flow channels 2 a, 2 d to 2 i. The piezoelectric unit315 stops the driving thereof by the instruction data D inputted fromthe CPU 32. This control disables any of the seventeen element bagportions E1 to E17, the twenty element bag portions E41 to E60 and theelement bag portion array E100 of the applications #1 to #3 to give theconcave and convex touch feeling to the operator's finger.

Thereafter, the process shifts to the step ST38 where the end of theinput processing in the mobile phone 710 is judged. For example, the CPU32 detects the power-OFF information. If the power-OFF information isnot detected, the process returns to the step ST21 where theabove-mentioned processing is repeated. If the power-OFF information isdetected, the input processing in the mobile phone 710 ends.

In this manner, the mobile phone 710 as the fourth embodiment isprovided with the embodiment of the input device 400. The layered sheetunit 140 for presenting sense of touch includes the three layeredtouch-sensitive variable sheet units 141 to 143 and the blower 3 b sendsthe compressed air to the element bag portion array E100 of thetouch-sensitive variable sheet unit 141, the element bag portions E41 toE60 of the touch-sensitive variable sheet unit 142 or the element bagportions E1 to E17 of the touch-sensitive variable sheet unit 143.

Consequently, in the predetermined positions of the base member 104, theelement bag portion array E100 may present the sense of touch for givingthe concave and convex feeling with respect to the operator's finger orthe like by the protuberant shape depending on the respective swellingof the element bag portion array E100. Also, in the predeterminedpositions of the base member 105, the element bag portions E41 to E60may present the sense of touch for giving the concave and convex feelingwith respect to the operator's finger or the like by the protuberantshape depending on the respective swelling of the element bag portionsE41 to E60. Further, in the predetermined positions of the base member106, the element bag portions E1 to E17 may present the sense of touchfor giving the concave and convex feeling with respect to the operator'sfinger or the like by the protuberant shape depending on the respectiveswelling of the element bag portions E1 to E17.

Accordingly, it is possible to execute the operation panel building mode(icon image+sense-of-touch-representing unit) by the sense of touchrepresentation function depending on the layered sheet unit 140 and bythe display function of the icon image of the display unit 29, so thatthe mobile phone 710 with the touch-sensitive variable sheet functionfor the icon touch, which is programmable between the layers, can beprovided. Moreover, it is possible to improve the miniaturization andthe operability of the input device 400, thereby enabling the reductionof the miss-operation, the cost down and the simplification of themanufacturing process of the mobile phone 710 to be realized.

Embodiment 5

FIGS. 29A and 29B show a configuration of a touch-sensitive sheet member150 as a fifth embodiment and a driving example thereof. In thisexample, the CPU 32 for controlling the touch-sensitive sheet member 150for representing a sense of touch controls a driving power supply 55 soas to supply a driving voltage to an element muscle portion 54 oftouch-sensitive sheet member 150 corresponding to image contentsdisplayed on the display unit 29, so that the element muscle portions 54is available at predetermined positions of a base frame portion 53corresponding to the image contents.

The touch-sensitive sheet member 150 shown in FIG. 29A contains anelectrode 51 for upper portion, an electrode 52 for lower portion, thesheet shaped base frame portion 53 and the element muscle portion 54.The base frame portion 53 constitutes the base member and formsapertures 53 a each having a predetermined aperture diameter. Theelement muscle portion 54 for representing a sense of touch is insertedin each of the apertures 53 a. For the base frame portion 53, atransparent soft silicon rubber member of the hardness 20° to 40° isused. The apertures 53 a are formed at predetermined positions of thebase frame portion 53. For the element muscle portion 54, a polymermaterial (artificial muscle) having transparency and also electricconductivity is used. The polymer material includes a flexible andstrong electric conductive Embra (trademark) film and an electricconductive gel polymer which is largely swellable in good solvent. Anoperation voltage of each of them is around 1.5V.

The element muscle portion 54 inserted in each of the apertures 53 a issandwiched between the electrode 51 and the electrode 52 from theupward/downward directions. The electrode 51 and the electrode 52 havepredetermined sizes and a predetermined driving voltage is appliedbetween the electrodes 51, 52. The electrode 51 and the electrode 52with common pattern or individually divided pattern are applied. For theelectrodes 51, 52, a transparent ITO film is used. According to theoperation principle of this element muscle portion 54, the expansion andcontraction motion thereof is obtained by exchanging polarity of the DCvoltage which is applied to the electrodes 51, 52.

In the touch-sensitive sheet member 150 shown in FIG. 29B, the electrode51 and the electrode 52 are connected to the driving power supply 55constituting the power supply unit as a medium-supplying unit, whichsupplies the driving voltage (medium) to the electrodes 51, 52sandwiching the polymer material therebetween. For the driving powersupply 55, a direct-current power supply is used. The driving powersupply 55 outputs ±DC voltage of around 1.0 to 3.0V. For example, whenthe voltage of plus polarity is applied to the electrode 51 and thevoltage of minus polarity is applied to the electrode 52 from thedriving power supply 55, minus ions are taken into the element muscleportion 54, so that the element muscle portion 54 swells.

On the other hand, when the voltage of minus polarity is applied to theelectrode 51 and the voltage of plus polarity is applied to theelectrode 52 from the driving power supply 55, minus ions are taken outof the element muscle portion 54, so that the element muscle portion 54contracts.

Also, when the driving voltage is applied to the electrodes 51, 52sandwiching an electric conductive elastomer (artificial muscle) ofsilicon, an acryl or the like therebetween, the electrodes are broughtcloser to each other. Consequently, the electric conductive elastomerleaks out to the outside of the electrodes 51, 52. When the supply ofthe driving voltage to the electrodes 51, 52 is stopped, the electrodes51, 52 and also the electric conductive elastomer return to the originalshapes if they are within the elastic displacement region.

By the way, the contraction rate of the human muscle is 20% and themaximum occurrence force is around 0.35 MPa (1 MPa=10 kgf/cm²). On theother hand, according to the high-occurrence force type artificialmuscle, if the driving voltage is 1.5V, the deformation rate thereof is12% to 15% and the maximum occurrence force is around 49 MPa. Also,according to the high-contraction type artificial muscle, if the drivingvoltage is 1.5V, the deformation rate thereof is 20% to 40% and themaximum occurrence force is around 2 to 10 MPa.

The touch-sensitive sheet member 150 is constituted in this manner andwhen the driving voltage is supplied to the electrodes 51, 52 arrangedin the upward/downward directions of the element muscle portion 54 fromthe driving power supply 55, the element muscle portion 54 may functionas an electric conductive polymer actuator in which the expansion andcontraction motion of the swelling, the contraction or the like occursin approximately two seconds. Consequently, in the spots of or at thepredetermined positions of the base frame portion 53, the element muscleportion 54 can present the sense of touch for giving the concave andconvex feeling with respect to the operator's finger 30 a by theprotuberant shape depending on the pressure change of the element muscleportion 54 or by the original shape when supplying no driving voltage.

FIG. 30 shows a configuration of an input device 500 to which theembodiment of the touch-sensitive sheet member 150 is applied. In thisembodiment, the input device 500 which can carry out the operation panelbuilding mode is provided. In the operation panel building mode,seventeen element muscle portions G1 to G17 constituting a first groupand/or eight element muscle portions G18 to G25 constituting a secondgroup, which are provided on the same plane of the base frame portion53, are selectable for every group.

To the input device 500 shown in FIG. 30 to which the touch-sensitivesheet member 150 shown in FIG. 29 is applied, any information isinputted by the slide and/or press operation depending on the finger orthe like of the operator 30 (operation body). The input device 500includes the display unit 29, the input detection unit 45 and atouch-sensitive variable sheet unit 145.

The display unit 29 has an operation surface and displays a plurality ofpush button switch images at a time of the input operation. The pushbutton switch images constitute icon images for the input operation. Thepush button switch images include a key K1 of numeral “1” to a key K10of numeral “0”, a key K11 of symbol “*”, a key K12 of a symbol “#” orthe like, a key K13 of determination “O” of a cross key, a left facingarrow key K14 thereof, an upward facing arrow key K15 thereof, a rightfacing arrow key K16 thereof, a downward facing arrow key K17 thereof, akey K18 of “etc”, a key K19 of “REW”, a left facing arrow stop key K20,a right facing arrow stop key K21, a left facing fast-forward key K22, afast-forward key K23, a reproduction key K24 and a stop key K25 or thelike. As the display unit 29, a color organic EL display device or aliquid crystal display device (LCD device) is used.

The input detection unit 45 which constitutes the detection unit isprovided on the upper portion of the display unit 29. The inputdetection unit 45 includes the operation surface. The input detectionunit 45 is provided on the upper portion of the display unit 29 andoperates so as to detect the slide position of the operator's finger orthe like. As the input detection unit 45, for example, a capacitivetouch panel is used. With respect to the input detection unit 45,anything is available only if the cursoring and the selection functioncan be distinguished. For example, other than the capacitive inputdevice, it also may be a resistive touch panel, an input device of asurface acoustic wave system (SAW) or an optical system, a tact switchof a multi stage system or the like. Preferably, it may be enough if theinput device has a constitution by which position detection informationand press detection information can be applied to a control system.

The transparent touch-sensitive variable sheet unit 145 constituting thetouch-sensitive sheet member is provided on the upper portion of theinput detection unit 45. The touch-sensitive variable sheet unit 145 isprovided so as to cover the whole of the input detection unit 45 and isslid and/or pressed down along the operation surface of the display unit29. It is needless to say that the touch-sensitive variable sheet unit145 may have a configuration covering a portion of the input detectionunit 45. The touch-sensitive variable sheet unit 145 is provided withthe embodiment of the touch-sensitive sheet member 150 having afacing-electrode structure.

In this embodiment, the touch-sensitive variable sheet unit 145 has thetransparent base frame portion 53. The base frame portion 53 haspredetermined hardness and also has twenty five elliptical apertures r1to r25. As the base frame portion 53, a polycarbonate (PC), an acrylicresin (PMMA) or the like having thickness of around 0.01 to 0.5[mm] isused.

An electrode pattern 51 a for first group and an electrode pattern 51 bfor second group are electrically divided and arranged in parallel onthe upper portion of the base frame portion 53. The electrode patterns51 a, 51 b are provided on an insulated base sheet 51A. An electrodepattern 52 a for first group and an electrode pattern 52 b for secondgroup are electrically divided and arranged in parallel on the lowerportion of the base frame portion 53. The electrode patterns 52 a, 52 bare provided on an insulated base sheet 52A. Element muscle portions G1to G25 each having predetermined volume are arranged so as to beinserted into the apertures r1 to r25 of the base frame portion 53 oneby one. The element muscle portions G1 to G25 are also sandwichedbetween the electrode patterns 51 a, 51 b and the electrode patterns 52a, 52 b.

For example, the element muscle portion G1 is inserted into the aperturer1 of the base frame portion 53 or is integrally molded to the baseframe portion 53. Similarly, the element muscle portion G2, the elementmuscle portion G3, the element muscle portion G4, the element muscleportion G5, the element muscle portion G6, the element muscle portion G7and the element muscle portion G8 are inserted into the aperture r2, theaperture r3, the aperture r4, the aperture r5, the aperture r6, theaperture r7 and the aperture r8, respectively or each is integrallymolded to the base frame portion 53. Further, the element muscle portionG9, the element muscle portion G10, the element muscle portion G11, theelement muscle portion G12, the element muscle portion G13, the elementmuscle portion G14, the element muscle portion G15, the element muscleportion G16 and the element muscle portion G17 are inserted into theaperture r9, the aperture r10, the aperture r11, the aperture r12, theaperture r13, the aperture r14, the aperture r15, the aperture r16 andthe aperture r17, respectively or each is integrally molded to the baseframe portion 53.

Also, the element muscle portion G18, the element muscle portion G19,the element muscle portion G20, the element muscle portion G21, theelement muscle portion G22, the element muscle portion G23, the elementmuscle portion G24 and the element muscle portion G25 are inserted intothe aperture r18, the aperture r19, the aperture r20, the aperture r21,the aperture r22, the aperture r23, the aperture r24 and the aperturer25, respectively or each is integrally molded to the base frame portion53. In a case in which the above-mentioned insertion method is employed,the respective element muscle portions G1 to G25 is bonded to theelectrode patterns 52 a, 52 b through ring shaped double-sided tapes 56.The element muscle portions G1 to G25 constitute thesense-of-touch-representing unit. Each of the element muscle portions G1to G25 has, for example, an elliptical cylinder shape and thickness ofaround 0.01 to 0.5 [mm].

In the above-mentioned base frame portion 53, the apertures r1 to r12for the keys of numerals “0” to “9”, the key of symbol “*”, the key ofsymbol “#” or the like and the apertures r13 to r17 for the cross key,which correspond to the icon images for the input operation,respectively have elliptical shapes. The above-mentioned element muscleportions G1 to G25 are arranged corresponding to the keys K1 to K25 ofvarious kinds of functions.

For example, the element muscle portion G1 is arranged on the key K1 ofnumeral “1” of the icon image displayed on the display unit 29. Theelement muscle portion G2 is arranged on the key K2 of numeral “2” ofthe icon image displayed on the display unit 29. The element muscleportion G3 is arranged on the key K3 of numeral “3” of the icon imagedisplayed on the display unit 29. The element muscle portion G4 isarranged on the key K4 of numeral “4” of the icon image displayed on thedisplay unit 29. The element muscle portion G5 is arranged on the key K5of numeral “5” of the icon image displayed on the display unit 29. Theelement muscle portion G6 is arranged on the key K6 of numeral “6” ofthe icon image displayed on the display unit 29. The element muscleportion G7 is arranged on the key K7 of numeral “7” of the icon imagedisplayed on the display unit 29. The element muscle portion G8 isarranged on the key K8 of numeral “8” of the icon image displayed on thedisplay unit 29. The element muscle portion G9 is arranged on the key K9of numeral “9” of the icon image displayed on the display unit 29. Theelement muscle portion G10 is arranged on the key K10 of numeral “0” ofthe icon image displayed on the display unit 29.

Also, the element muscle portion G11 is arranged on the key K11 ofsymbol “*” of the icon image displayed on the display unit 29. Theelement muscle portion G12 is arranged on the key K12 of symbol “#” ofthe icon image displayed on the display unit 29. The element muscleportion G13 is arranged on the key of determination “O” of the cross keyof the icon image displayed on the display unit 29. The element muscleportion G14 is arranged on the left facing arrow key of the icon imagedisplayed on the display unit 29. The element muscle portion G15 isarranged on the upward facing arrow key of the icon image displayed onthe display unit 29. The element muscle portion G16 is arranged on theright facing arrow key of the icon image displayed on the display unit29. The element muscle portion G17 is arranged on the downward facingarrow key of the icon image displayed on the display unit 29.

Further, the element muscle portion G18 is arranged on the key of “etc”of the icon image displayed on the display unit 29. The element muscleportion G19 is arranged on the key of “REW” of the icon image displayedon the display unit 29. The element muscle portion G20 is arranged onthe left facing arrow stop key of the icon image displayed on thedisplay unit 29. The element muscle portion G21 is arranged on the rightfacing arrow stop key of the icon image displayed on the display unit29. The element muscle portion G22 is arranged on the left facingfast-forward key of the icon image displayed on the display unit 29. Theelement muscle portion G23 is arranged on the fast-forward key of theicon image displayed on the display unit 29. The element muscle portionG24 is arranged on the reproduction key of the icon image displayed onthe display unit 29. The element muscle portion G25 is arranged on thestop key of the icon image displayed on the display unit 29.

As the electrode patterns 51 a, 51 b, 52 a, 52 b which sandwich theseelement muscle portions G1 to G25, there is used a transparent thin filmmaterial having transmissivity and a refractive index which areapproximately equal to transmissivity and a refractive index of the baseframe portion 53. As the electrode patterns 51 a, 51 b, 52 a, 52 b,there is used, for example, an ITO film of the film thickness of around0.1 to 0.125 [mm] The hardness thereof is around 20° to 40°.

The electrode patterns 51 a, 51 b and the electrode patterns 52 a, 52 bare connected with the driving power supply, not shown, which appliesthe driving voltage to the twenty five element muscle portions G1 to G25for presenting a sense of touch, for every group, which are sandwichedbetween the electrode patterns 51 a, 51 and the electrode patterns 52 a,52 b. The direct-current power supply as explained in FIG. 29B is usedfor the driving power supply 55.

The following will describe an operation example of the input device500. FIGS. 31A and 31B show an operation example of the input device500.

The input device 500 shown in FIG. 31A includes the touch-sensitivesheet member 150 shown in FIG. 30. In the touch-sensitive sheet member150 shown in FIG. 31A, the driving power supply 55 connected to theelectrode pattern 51 a of the base sheet 51A and the electrode pattern52 a of the base sheet 52A does not supply the driving voltage. In thiscase, the original shapes of the element muscle portions G1, G4 and thelike which are sandwiched between the electrode pattern 51 a and theelectrode pattern 52 a are kept without swelling.

In the touch-sensitive sheet member 150 shown in FIG. 31B, the drivingpower supply 55 supplies the driving voltage to the electrode patterns51 a, 52 a. For example, the driving power supply 55 supplies the DCvoltage of around +1.5V to the electrode patterns 51 a, 52 a. In thiscase, the element muscle portions G1, G4 and the like which aresandwiched between the electrode pattern 51 a and the electrode pattern52 a swell and the resulted convex shaped postures thereof are kept.

In a case in which the first group is selected in the input device 500according to the above-mentioned operation principle of thetouch-sensitive sheet member 150, the voltage of plus polarity isapplied to the electrode pattern 51 a and the electrode pattern 52 a.This applied voltage enables the seventeen element muscle portions G1 toG17 which are sandwiched between the electrode pattern 51 a and theelectrode pattern 52 a to swell at the same time, which changing theirpostures to the convex shaped ones.

Similarly, in a case in which the second group is selected in the inputdevice 500, the voltage of plus polarity is applied to the electrodepattern 51 b and the electrode pattern 52 b. This applied voltageenables the eight element muscle portions G18 to G25 which aresandwiched between the electrode pattern 51 b and the electrode pattern52 b to swell at the same time, which changing their postures to theconvex shaped ones. Each of the element muscle portions G1 to G25returns to their original shapes when the applying of the drivingvoltage to the electrode patterns 51 a, 51 b, the electrode patterns 52a, 52 b or the like is stopped. The convex shaped postures of suchelement muscle portions G1 to G17 or G18 to G25 respectively give theconcave and convex touch feelings to the operator's finger or the likewhen the slide operation or the press operation is executed.

The configuration and the information processing example of the mobilephone mounted with the input device 500 are approximately similar as theconfiguration of the mobile phone 600 shown in FIG. 20 and theinformation processing example shown in FIG. 23, so that the explanationthereof will be omitted. It should be noted that with respect to mobilephone mounted with the input device 500, the block diagram can beapplied by reading the input device 300 with the input device 500 andfurther, by reading the touch-sensitive variable sheet unit 103 with thetouch-sensitive sheet member 150 in the block diagram shown in FIG. 20.Also, the flowchart can be applied by reading the element bag portionswith the element muscle portions and by reading air-circulation unit 3Awith the driving power supply 55 in the description on the flowchartshown in FIG. 23.

In the input device 500 thus configured, the driving power supply 55applies the DC driving voltage to the element muscle portions G1 to G17or the element muscle portions G18 to G25 for every group. Consequently,in the predetermined positions of the base frame portion 53, the elementmuscle portions G1 to G25 may present the sense of touch for giving theconcave and convex feeling by the protuberant shape or the cave-in shapedepending on the swelling of the element muscle portions G1 to G25 or bythe original shape without conducting electricity with respect to theoperator's finger or the like.

The following will describe a modification example (No. 1) of thetouch-sensitive sheet member 150. FIGS. 32A and 32B show a configurationand a driving example of a touch-sensitive sheet member 151 that isapplicable to the input device 500. The touch-sensitive sheet member 151shown in FIG. 32A includes the electrode 51 for upper portion, theelectrode 52 for lower portion, a sheet shaped base frame portion 531and element muscle portions 541 each having C shape.

The base frame portion 531 constitutes the base member and formsC-shaped apertures 53 b each having a predetermined aperture ring width.Each of the C-shaped element muscle portions 541 for presenting a senseof touch is inserted into this aperture 53 b. As the base frame portion531, a transparent soft silicon rubber member having the hardness of 20°to 40° is used.

The apertures 53 b are arranged at predetermined positions of the baseframe portion 531. As the element muscle portions 541, a same materialas that used for ones of the touch-sensitive sheet member 150 is used.Each of the element muscle portions 541 which are inserted into theapertures 53 b is sandwiched between the electrode 51 and the electrode52 from the upward/downward directions. A predetermined driving voltageis applied between the electrodes 51, 52. As the electrodes 51, 52, atransparent ITO film is used. It should be noted that members having thesame name and numeral as those used in the touch-sensitive sheet member150 have the same functions, so that the explanation thereof will beomitted.

In the touch-sensitive sheet member 151 shown in FIG. 32B, the electrode51 and the electrode 52 are also connected with the driving power supplywhich supplies the driving voltage to the electrodes 51, 52. Theoperation principle of this element muscle portion 541 is similar tothat of the touch-sensitive sheet member 150, so that the explanationthereof will be omitted.

The touch-sensitive sheet member 151 is constituted in this manner sothat when the driving power supply 55 supplies the driving voltage tothe electrodes 51, 52 arranged in the upward/downward directions of eachof the element muscle portions 541, each of the element muscle portions541 may function as an electric conductive polymer actuator in which theexpansion and contraction motion such as the swelling in the C-shape andthe contraction is available for approximately two seconds.Consequently, in the spots of or the predetermined positions of the baseframe portion 531, the element muscle portions 541 may present the senseof touch for giving the concave and convex feeling with respect to theoperator's finger 30 a by the protuberant shape depending on thepressure change of the element muscle portion 541 or by the originalshape without supplying the driving voltage thereto. Thus, it becomespossible to provide the input device 500 or the like to which thetouch-sensitive sheet member 151 is applied.

The following will describe a modification example (No. 2) of thetouch-sensitive sheet member 150. FIGS. 33A and 33B show a configurationand a driving example of a touch-sensitive sheet member 152 that isapplicable to the input device 500. The touch-sensitive sheet member 152shown in FIG. 33A includes the electrode 51 for upper portion, theelectrode 52 for lower portion, a sheet shaped base frame portion 532and element muscle portions 542 each having a hemispheric shape.

The base frame portion 532 constitutes the base member and formshemispheric shaped recess portions 53 c each having a predeterminedopening diameter. Each of the hemispheric shaped element muscle portions542 for presenting a sense of touch is inserted and held in the recessportion 53 c. As the base frame portion 532, a transparent soft siliconrubber member having the hardness of 20° to 40° is used.

The recess portions 53 c are arranged at predetermined positions of thebase frame portion 532. As the element muscle portions 542, a samematerial as that used for ones of the touch-sensitive sheet member 150is used. Each of the element muscle portions 542 which are inserted inthe recess portions 53 c is sandwiched between the electrode 51 and theelectrode 52 from the upward/downward directions. A predetermineddriving voltage is applied between the electrodes 51, 52. As theelectrodes 51, 52, a transparent ITO film is used. It should be notedthat members having the same name and numeral as those used in thetouch-sensitive sheet member 150 have the same functions, so that theexplanation thereof will be omitted.

In the touch-sensitive sheet member 152 shown in FIG. 33B, the electrode51 and the electrode 52 are also connected with the driving power supplywhich supplies the driving voltage to the electrodes 51, 52. Theoperation principle of this element muscle portion 542 is similar tothat of the touch-sensitive sheet member 150, so that the explanationthereof will be omitted.

The touch-sensitive sheet member 152 is constituted in this manner sothat when the driving power supply 55 supplies the driving voltage tothe electrodes 51, 52 arranged in the upward/downward directions of eachof the element muscle portions 542, each of the element muscle portions542 may function as an electric conductive polymer actuator in which theexpansion and contraction motion such as the swelling in the hemisphericshape and the contraction in a concave shape is allowed. Consequently,in the spots of or the predetermined positions of the base frame portion532, the element muscle portions 542 may present the sense of touch forgiving the concave and convex feeling with respect to the operator'sfinger 30 a by the protuberant shape depending on the pressure change ofthe element muscle portion 542 or by the original shape withoutsupplying the driving voltage. Thus, it becomes possible to provide theinput device 500 or the like to which the touch-sensitive sheet member152 is applied.

The following will describe a modification example (No. 3) of thetouch-sensitive sheet member 150. FIGS. 34A and 34B show a configurationand a driving example of a touch-sensitive sheet member 153 that isapplicable to the input device 500. The touch-sensitive sheet member 153shown in FIG. 34A includes the electrode 51 for upper portion, theelectrode 52 for lower portion, a sheet shaped base frame portion 533and element muscle portions 543 each having a mortar shape.

The base frame portion 533 constitutes the base member and forms reversemortar shaped recess portions 53 d each having a predetermined openingdiameter. Each of the mortar shaped element muscle portions 543 forpresenting a sense of touch is inserted and held in the recess portion53 d. As the base frame portion 533, a transparent soft silicon rubbermember having the hardness of 20° to 40° is used.

The recess portions 53 d are arranged at predetermined positions of thebase frame portion 533. As the element muscle portions 543, a samematerial as that used for ones of the touch-sensitive sheet member 150is used. Each of the element muscle portions 543 which are inserted inthe recess portions 53 d is sandwiched between the electrode 51 and theelectrode 52 from the upward/downward directions. A predetermineddriving voltage is applied between the electrodes 51, 52. As theelectrodes 51, 52, a transparent ITO film is used. It should be notedthat members having the same name and numeral as those used in thetouch-sensitive sheet member 150 have the same functions, so that theexplanation thereof will be omitted.

In the touch-sensitive sheet member 153 shown in FIG. 34B, the electrode51 and the electrode 52 are also connected with the driving power supplywhich supplies the driving voltage to the electrodes 51, 52. Theoperation principle of this element muscle portion 543 is similar tothat of the touch-sensitive sheet member 150, so that the explanationthereof will be omitted.

The touch-sensitive sheet member 153 is constituted in this manner sothat when driving power supply 55 supplies the driving voltage to theelectrodes 51, 52 arranged in the upward/downward directions of each ofthe element muscle portion 543, each of the element muscle portions 543may function as an electric conductive polymer actuator in which theexpansion and contraction motion such as the swelling in the mortarshape and the contraction in a concave shape is allowed. Consequently,in the spots of or the predetermined positions of the base frame portion533, the element muscle portion 543 may present the sense of touch forgiving the concave and convex feeling with respect to the operator'sfinger 30 a by the protuberant shape depending on the pressure change ofthe element muscle portion 543 or by the original shape withoutsupplying the driving voltage. Thus, it becomes possible to provide theinput device 500 or the like to which the touch-sensitive sheet member153 is applied.

Embodiment 6

FIGS. 35A, 35B and 35C show a configuration of a touch-sensitive sheetmember 160 as a sixth embodiment and driving examples thereof. In thisembodiment, the CPU 32 for controlling the touch-sensitive sheet member160 for presenting a sense of touch controls a driving power supply 55Ato supply the driving voltage to a muscular sheet portion 54A of thetouch-sensitive sheet member 160 corresponding to the image contentsdisplayed on the display unit 29, so that the muscular sheet portion 54Ais available on the electrode-forming positions corresponding to theimage contents.

The touch-sensitive sheet member 160 shown in FIG. 35A includes aplurality of electrodes 51 for upper portion, a plurality of electrodes52 for lower portion and the muscular sheet portion 54A. The muscularsheet portion 54A constitutes the base member and thesense-of-touch-representing unit. The muscular sheet portion 54A isconstituted such that the convex and concave shapes are built at thepositions corresponding to a plurality of operation key elements of theicon images of the operation screen. As the muscular sheet portion 54A,a polymer material (artificial muscle) having transparency and alsoelectric conductivity is used. The polymer material includes a flexibleand strong electric conductive Embra (trademark) film and an electricconductive gel polymer which is largely swellable in good solvent. Anoperation voltage of each of them is around 1.5V.

The plurality of electrodes 51 each having a predetermined area areprovided at the upper portion of the muscular sheet portion 54A. Theplurality of electrodes 52 each having an area, which face to thepredetermined electrodes 51, are provided at the lower portion of themuscular sheet portion 54A. In a case in which the touch-sensitive sheetmember 160 of the facing electrode structure is constituted, themuscular sheet portion 54A is sandwiched between the electrode 51 of apredetermined position and the electrode 52 of the predeterminedposition from the upward/downward directions. A predetermined drivingvoltage is applied between the electrodes 51, 52, similarly as the fifthembodiment. Each of the electrodes 51, 52 is divided individually forevery plural operation key element, which is different from the fifthembodiment. AS the electrodes 51, 52, a transparent ITO film is used.According to the operation principle of this muscular sheet portion 54A,the expansion and contraction motion thereof is obtained for everyoperation key element by exchanging polarity of the DC voltage which isapplied to the respective electrodes 51, 52.

In the touch-sensitive sheet member 160 shown in FIG. 35B, the electrode51 and electrode 52 are connected with the driving power supply 55Awhich supplies the driving voltage (medium) is supplied between theelectrode 51 and the corresponding electrode 52. As the driving powersupply 55A, a power supply unit including a direct-current power supplyand an electrode selection function is used. The driving power supply55A outputs ±DC voltage of around 1.0 to 3.0V. For example, when thevoltage of plus polarity is applied to the electrode 51 and the voltageof minus polarity is applied to the electrode 52 from the driving powersupply 55A, minus ions are taken into the muscular sheet portion 54A, sothat the muscular sheet portion 54A swells. On the other hand, when thevoltage of minus polarity is applied to the electrodes 51 and thevoltage of plus polarity is applied to the electrodes 52 from thedriving power supply 55A, minus ions are taken out of the muscular sheetportion 54A, so that the muscular sheet portion 54A contracts.

The touch-sensitive sheet member 160 as the sixth embodiment isconstituted in this manner and when the driving voltage is individuallysupplied to the respective electrodes 51, 52 arranged on theupward/downward directions of the muscular sheet portion 54A from thedriving power supply 55A, the muscular sheet portion 54A may function asan electric conductive polymer actuator in which the expansion andcontraction motion of the swelling, the contraction or the like isavailable for every operation key element. Consequently, in the spots ofor at the predetermined positions of the touch-sensitive sheet member160, the muscular sheet portion 54A may present the sense of touch forgiving the concave and convex feeling with respect to the operator'sfinger 30 a by the protuberant shape depending on the pressure change ofthe muscular sheet portion 54A or by the original shape withoutsupplying the driving voltage.

Although, in the above-mentioned embodiment, a case where the electrode51 and the electrode 52 are faced each other has been described, theyare not limited to this; as a touch-sensitive sheet member 160A shown inFIG. 35C, the electrode 51 and the electrode 52 may be arranged inparallel by keeping a predetermined distance on one side surface of themuscular sheet portion 54A, for example, on the rear surface of themuscular sheet portion 54A. Even for such a constitution, the muscularsheet portion 54A on the upper portion of the electrode 51 and theelectrode 52 may present the sense of touch for giving the concave andconvex feeling with respect to the operator's finger 30 a by theprotuberant shape depending on the pressure change of the muscular sheetportion 54A or by the original shape without supplying the drivingvoltage. Portions of double-dashed lines shown in FIGS. 35B and 35Cindicate a transparent film member for surface protection and atransparent film member for insulating between layers.

Embodiment 7

FIG. 36 shows a configuration of an input device 700 as a seventhembodiment. In this embodiment, the input device 700 in which theembodiments of the touch-sensitive sheet members 150 and 160A arecombined. There is provided the input device 700 that is possible toexecute the operation panel building mode in which seventeen elementmuscle portions G1 to G17 forming a first group and/or eight elementmuscle portions G18 to G25 forming a second group can be selected forevery group.

Also in this embodiment, the CPU 32 for controlling the touch-sensitivesheet member 170 for presenting a sense of touch executes the drivingcontrol so as to supply the driving voltage to the element muscleportions G1 to G25 of the touch-sensitive sheet member 170 correspondingto the image contents displayed on the display unit 29, so that theelement muscle portions G1 to G25 are available at the electrode-formingpositions corresponding to the image contents.

To the input device 700 shown in FIG. 36, the structure of the elementmuscle portions G1 to G25 of the touch-sensitive sheet member 150 shownin the fifth embodiment and the structure of the electrodes 51, 52 ofthe touch-sensitive sheet member 160 relating to the sixth embodimentare applied. In the input device 700, any information is inputted by theslide and/or press operation depending on the finger or the like of theoperator 30 (operation body). The input device 700 includes the displayunit 29, the input detection unit 45 and the touch-sensitive sheetmember 170.

The display unit 29, similarly as the fifth embodiment, at a time of theinput operation, displays the icon images of a key K1 of numeral “1” toa key K10 of numeral “0”, a key K11 of symbol “*”, a key K12 of a symbol“#” or the like, a key K13 of determination “O” of a cross key, a leftfacing arrow key K14 thereof, an upward facing arrow key K15 thereof, aright facing arrow key K16 thereof, a downward facing arrow key K17thereof, a key K18 of “etc”, a key K19 of “REW”, a left facing arrowstop key K20, a right facing arrow stop key K21, a left facingfast-forward key K22, a fast-forward key K23, a reproduction key K24 anda stop key K25 or the like. As the display unit 29, a color organic ELdisplay device or a liquid crystal display device (LCD device) is used.

The input detection unit 45 which constitutes the detection unit isprovided on the upper portion of the display unit 29. The inputdetection unit 45 includes the operation surface. The input detectionunit 45 is provided on the upper portion of the display unit 29 andoperates so as to detect the slide position of the operator's finger orthe like. As the input detection unit 45, for example, a capacitivetouch panel is used. With respect to the input detection unit 45,anything is available only if the cursoring and the selection functioncan be distinguished. For example, other than the capacitive inputdevice, it also may be a resistive touch panel, an input device of asurface acoustic wave system (SAW) or an optical system, a tact switchof a multi stage system or the like. Preferably, it may be enough if theinput device has a constitution by which position detection informationand press detection information can be applied to a control system.

The transparent touch-sensitive variable sheet unit 170 constituting thetouch-sensitive sheet member is provided on the upper portion of theinput detection unit 45. The touch-sensitive variable sheet unit 170 isprovided so as to cover the whole of the input detection unit 45 and isslid and/or pressed down along the operation surface of the display unit29. It is needless to say that the touch-sensitive variable sheet unit170 may have a configuration covering a portion of the input detectionunit 45. The touch-sensitive variable sheet unit 170 is provided withthe individual insertion structure of the element muscle portions G1 toG25 of the touch-sensitive sheet member 150 shown in the fifthembodiment and the electrode parallel arrangement structure of thetouch-sensitive sheet member 160A relating to the sixth embodiment.

In this embodiment, the touch-sensitive sheet member 170 includes aninsulated and transparent electrode film portion 511 on the upperportion of the input detection unit 45. The electrode film portion 511is composed of a polyethylene terephthalate (PET) based transparentmaterial having the thickness of around 0.1 [mm] and an ITO film. Aplurality of positive/negative electrode patterns 51 a, 52 acorresponding to the respective operation key elements for first groupand a plurality of positive/negative electrode patterns 51 b, 52 bcorresponding to the respective operation key elements for second groupare electrically divided and arranged in parallel in the electrode filmportion 511. These plural electrode patterns 51 a, 52 a are connected inparallel and at the same time, the plural electrode patterns 51 b, 52 bcorresponding to the respective operation key elements for second groupare connected in parallel. Wiring patterns which are connected inparallel respectively and arranged in the positive/negative manner aregathered at a pull-out terminal 512.

In the touch-sensitive sheet member 170, there is provided a transparentbase frame portion 53 as explained in the fifth embodiment. The baseframe portion 53 has predetermined hardness and also has twenty fiveelliptical apertures r1 to r25. As the base frame portion 53, apolycarbonate (PC), an acrylic resin (PMMA) or the like having thicknessof around 0.01 to 0.5[mm] is used. Also in this embodiment, the elementmuscle portions G1 to G25 are arranged in the inside of the ellipticalconcave shaped portions constituted by the base frame portion 53 and theelectrode film portion 511. For example, each of the element muscleportions G1 to G25 has predetermined volume and the element muscleportions G1 to G25 are arranged by inserting them into the correspondingapertures r1 to r25 in the base frame portion 53 one by one.

For example, the element muscle portion G1 is inserted into the aperturer1 of the base frame portion 53 or is integrally molded to the baseframe portion 53. Similarly, the element muscle portion G2, the elementmuscle portion G3, the element muscle portion G4, the element muscleportion G5, the element muscle portion G6, the element muscle portion G7and the element muscle portion G8 are inserted into the aperture r2, theaperture r3, the aperture r4, the aperture r5, the aperture r6, theaperture r7 and the aperture r8, respectively or each is integrallymolded to the base frame portion 53. Further, the element muscle portionG9, the element muscle portion G10, the element muscle portion G11, theelement muscle portion G12, the element muscle portion G13, the elementmuscle portion G14, the element muscle portion G15, the element muscleportion G16 and the element muscle portion G17 are inserted into theaperture r9, the aperture r10, the aperture r11, the aperture r12, theaperture r13, the aperture r14, the aperture r15, the aperture r16 andthe aperture r17, respectively or each is integrally molded to the baseframe portion 53.

Also, the element muscle portion G18, the element muscle portion G19,the element muscle portion G20, the element muscle portion G21, theelement muscle portion G22, the element muscle portion G23, the elementmuscle portion G24 and the element muscle portion G25 are inserted intothe aperture r18, the aperture r19, the aperture r20, the aperture r21,the aperture r22, the aperture r23, the aperture r24 and the aperturer25, respectively or each is integrally molded to the base frame portion53. In a case in which the above-mentioned insertion method is employed,the respective element muscle portions G1 to G25 is bonded to theelectrode patterns 52 a, 52 b through ring shaped double-sided tapes 56.The element muscle portions G1 to G25 constitute thesense-of-touch-representing unit. Each of the element muscle portions G1to G25 has, for example, an elliptical cylinder shape and thickness ofaround 0.01 to 0.5 [mm].

A film portion 5 constituting a function of a lid portion is provided onthe upper portion of the base frame portion 53. As the film portion 5,there is used a transparent material having transmissivity and arefractive index which are approximately equal to transmissivity and arefractive index of the base frame portion 53. There is used, forexample, a zeonor (trademark) having the film thickness of around 25[μm]. The hardness thereof is around 20° to 40°.

In the above-mentioned base frame portion 53, the apertures r1 to r12for the keys of numerals “0” to “9”, the key of symbol “*”, the key ofsymbol “#” or the like and the apertures r13 to r17 for the cross key,which correspond to the icon images for the input operation,respectively have elliptical shapes. The above-mentioned element muscleportions G1 to G25 are arranged corresponding to the keys K1 to K25 ofvarious kinds of functions.

The element muscle portion G1 is arranged, similarly as the fifthembodiment, on the key K1 of numeral “1” of the icon image displayed onthe display unit 29. The element muscle portion G2 is arranged on thekey K2 of numeral “2” of the icon image displayed on the display unit29. The element muscle portion G3 is arranged on the key K3 of numeral“3” of the icon image displayed on the display unit 29. The elementmuscle portion G4 is arranged on the key K4 of numeral “4” of the iconimage displayed on the display unit 29. The element muscle portion G5 isarranged on the key K5 of numeral “5” of the icon image displayed on thedisplay unit 29. The element muscle portion G6 is arranged on the key K6of numeral “6” of the icon image displayed on the display unit 29. Theelement muscle portion G7 is arranged on the key K7 of numeral “7” ofthe icon image displayed on the display unit 29. The element muscleportion G8 is arranged on the key K8 of numeral “8” of the icon imagedisplayed on the display unit 29. The element muscle portion G9 isarranged on the key K9 of numeral “9” of the icon image displayed on thedisplay unit 29. The element muscle portion G10 is arranged on the keyK10 of numeral “0” of the icon image displayed on the display unit 29.

Also, the element muscle portion G11 is arranged on the key K11 ofsymbol “*” of the icon image displayed on the display unit 29. Theelement muscle portion G12 is arranged on the key K12 of symbol “#” ofthe icon image displayed on the display unit 29. The element muscleportion G13 is arranged on the key of determination “O” of the cross keyof the icon image displayed on the display unit 29. The element muscleportion G14 is arranged on the left facing arrow key of the icon imagedisplayed on the display unit 29. The element muscle portion G15 isarranged on the upward facing arrow key of the icon image displayed onthe display unit 29. The element muscle portion G16 is arranged on theright facing arrow key of the icon image displayed on the display unit29. The element muscle portion G17 is arranged on the downward facingarrow key of the icon image displayed on the display unit 29.

Further, the element muscle portion G18 is arranged on the key of “etc”of the icon image displayed on the display unit 29. The element muscleportion G19 is arranged on the key of “REW” of the icon image displayedon the display unit 29. The element muscle portion G20 is arranged onthe left facing arrow stop key of the icon image displayed on thedisplay unit 29. The element muscle portion G21 is arranged on the rightfacing arrow stop key of the icon image displayed on the display unit29. The element muscle portion G22 is arranged on the left facingfast-forward key of the icon image displayed on the display unit 29. Theelement muscle portion G23 is arranged on the fast-forward key of theicon image displayed on the display unit 29. The element muscle portionG24 is arranged on the reproduction key of the icon image displayed onthe display unit 29. The element muscle portion G25 is arranged on thestop key of the icon image displayed on the display unit 29.

As the electrode film portion 511 which holds these element muscleportions G1 to G25, there is used a transparent thin film materialhaving transmissivity and a refractive index which are approximatelyequal to transmissivity and a refractive index of the base frame portion53. For the electrode patterns 51 a, 51 b, 52 a, 52 b, there is used,for example, an ITO film having the film thickness of around 0.1 to0.125 [mm] The hardness thereof is around 20° to 40°.

The plurality of electrode patterns 51 a, 51 b and the plurality ofelectrode patterns 52 a, 52 b which are arranged in thepositive/negative manner in the electrode film portion 511 are connectedwith the driving power supply 55A, not shown in FIG. 36, which appliesthe driving voltage to the twenty five element muscle portions G1 to G25for presenting a sense of touch which are sandwiched between the filmportion 5 and the electrode film portion 511 for every group. For thedriving power supply 55A, there is used a power supply unit having thedirect-current power supply and the electrode selection function asexplained in FIG. 29.

The configuration and the information processing example of the mobilephone mounted with the input device 700 are approximately similar as theconfiguration of the mobile phone 600 shown in FIG. 20 and theinformation processing example shown in FIG. 23, so that the explanationthereof will be omitted. It should be noted that with respect to mobilephone mounted with the input device 700, the block diagram can beapplied by reading the input device 300 with the input device 700 andfurther, by reading the touch-sensitive variable sheet unit 103 with thetouch-sensitive sheet member 170 in the block diagram shown in FIG. 20.Also, the flowchart can be applied by reading the element bag portionswith the element muscle portions and by reading air-circulation unit 3Awith the driving power supply 55A in the description on the flowchartshown in FIG. 23.

In this manner, according to the input device 700 as the seventhembodiment, the driving power supply 55A applies the DC driving voltageto the element muscle portions G1 to G17 or the element muscle portionsG18 to G25 for every group. Consequently, at the positions correspondingto the respective operation keys of the base frame portion 53, theelement muscle portions G1 to G25 may present the sense of touch forgiving the concave and convex feeling by the protuberant shape or thecave-in shape depending on the swelling of the element muscle portionsG1 to G25 or by the original shape without conducting electricity withrespect to operator's finger or the like.

It is needless to say that the electrode patterns 51 a, 51 b, 52 a, 52 bmay be wired so as to correspond to the respective operation keys andare gathered at the terminal 512 without connecting the electrodepatterns 51 a, 51 b and the electrode patterns 52 a, 52 b in parallel,and the voltage-level of the DC driving voltage may be variably appliedto the element muscle portions G1 to G25 corresponding to the respectiveoperation keys from the driving power supply 55A. By constitution inthis manner, at the positions corresponding to the respective operationkey of the base frame portion 53, the respective element muscle portionsG1 to G25 may present the programmable sense of touch for giving theconcave and convex feeling by the protuberant shape or the cave-in shapein which the amount of swelling of the element muscle portions G1 to G25is variably adjusted or by the original shape without conductingelectricity with respect to operator's finger or the like.

Embodiment 8

FIG. 37 shows a configuration of an input device 800 as an eighthembodiment. In this embodiment, there is provided the input device 800in which the wiring pattern constituting the touch-sensitive sheetmember is concurrently used with a portion of the wiring patternconstituting the display unit 29. Also, in this embodiment, the CPU 32for controlling a touch-sensitive sheet member 180 for presenting asense of touch executes the driving control so as to supply the drivingvoltage to an electrically conductive rubber 182 of the touch-sensitivesheet member 180 corresponding to the image contents displayed on thedisplay unit 29, so that the electrically conductive rubber 182 isavailable at the electrode-forming positions corresponding to the imagecontents.

To the input device 800 shown in FIG. 37, the touch-sensitive sheetmember 160 relating to the sixth embodiment is applied. In the inputdevice 800, any information is inputted by the slide and/or pressoperation depending on the finger or the like of the operator 30(operation body). The input device 800 includes the film portion 5, theinput detection unit 45 and a display device 129 with thetouch-sensitive variable sheet function.

The display device 129 has the function of the display unit 29 explainedin the fifth embodiment and the facing electrodes structure of thetouch-sensitive sheet member 160 explained in the sixth embodiment. Thedisplay device 129, similarly as the fifth embodiment, at a time of theinput operation, displays the icon images of a key K1 of numeral “1” toa key K10 of numeral “0”, a key K11 of symbol “*”, a key K12 of a symbol“#” or the like, a key K13 of determination “O” of a cross key, a leftfacing arrow key K14 thereof, an upward facing arrow key K15 thereof, aright facing arrow key K16 thereof, a downward facing arrow key K17thereof, a key K18 of “etc”, a key K19 of “REW”, a left facing arrowstop key K20, a right facing arrow stop key K21, a left facingfast-forward key K22, a fast-forward key K23, a reproduction key K24 anda stop key K25 or the like. As the display unit 129, a color organic ELdisplay device or a liquid crystal display device (LCD device) is used.

The input detection unit 45 is provided on the upper portion of thedisplay unit 129. The input detection unit 45 includes the operationsurface. The input detection unit 45 is provided on the upper portion ofthe display unit 129 and operates so as to detect the slide position ofthe operator's finger or the like. As the input detection unit 45, forexample, a capacitive touch panel is used. With respect to the inputdetection unit 45, anything is available only if the cursoring and theselection function can be distinguished. For example, other than thecapacitive input device, it also may be a resistive touch panel, aninput device of a surface acoustic wave system (SAW) or an opticalsystem, a tact switch of a multi stage system or the like. Preferably,it may be enough if the input device has a constitution by whichposition detection information and press detection information can beapplied to a control system.

The film portion 5 is provided on the upper portion of the inputdetection unit 45. As the film portion 5, there is used a transparentmaterial having transmissivity and a refractive index which areapproximately equal to transmissivity and a refractive index of theinput detection unit 45. There is used, for example, a zeonor(trademark) having the film thickness of around 25 [μm]. The hardnessthereof is around 20° to 40°.

FIG. 38 shows a configuration of the display device 129 with atouch-sensitive variable sheet function. FIG. 39 shows a configurationof a cross-section of the display device 129. The display device 129shown in FIG. 38 includes a transparent touch-sensitive sheet member 180which constitutes the touch-sensitive sheet member and a display unit 29on the touch-sensitive sheet member 180. As the display unit 29, forexample, an organic EL device is used.

The touch-sensitive sheet member 180 is provided to support the whole ofthe lower surface of the display unit 29, and is slid and/or presseddown along the operation surface of the display unit 29. It is needlessto say that the touch-sensitive sheet member 180 may support a portionof the lower surface of the display unit 29.

The touch-sensitive sheet member 180 is provided with the structure ofthe muscular sheet portion 54A and the facing electrodes structure ofthe touch-sensitive sheet member 160 relating to the sixth embodiment.Further, a part of the wiring pattern of the display unit 29 isconcurrently used with the wiring pattern of the touch-sensitive sheetmember 180.

In this embodiment, the touch-sensitive sheet member 180 is constitutedby layering the electrically conductive rubber 182 and an intermediatelayer film 183 on a base film 181 as shown in FIG. 39. The base film 181is composed of a polyethylene terephthalate (PET) based transparentmaterial having the thickness of around 0.1 [mm] and an ITO film forminga wiring pattern group 57 which is patterned on the material. A wiringpitch of the wiring pattern group 57 is approximately around ½ to 1times of an arrangement pitch of the display pixel.

The electrically conductive rubber 182 is bonded on the upper portion ofthe base film 181 by an adhesive agent or the like. As the electricallyconductive rubber 182, a polymer material (artificial muscle) havingtransparency and also electric conductivity is used. The electricallyconductive rubber 182 includes a flexible and strong electric conductiveEmbra (trademark) film and an electric conductive gel polymer which islargely swellable in good solvent. An operation voltage of each of themis around 1.5V.

On the bottom surface of the electrically conductive rubber 182, theelectrodes 52 are arranged at the positions corresponding to therespective operation keys as shown in FIG. 39. The plurality ofelectrodes 52 are connected individually to the above-mentioned wiringpattern group 57. The intermediate layer film 183 is bonded on the upperportion of the electrically conductive rubber 182 by an adhesive agentor the like. As the intermediate layer film 183, an insulated andtransparent polyimide based film member is used.

The display unit 29 which forms the organic EL device is bonded on theupper portion of the intermediate layer film 183 by an adhesive agent orthe like. The display unit 29 includes a sealing layer 29 a, aself-light-emitting organic material 29 b, an intermediate layer film 29c, a base panel 29 d and an electrode pattern 29 e. The sealing layer 29a has a frame shape as shown in FIG. 38 and is provided on theintermediate layer film 183. The sealing layer 29 a seals theself-light-emitting organic material 29 b.

The intermediate layer film 29 c is bonded on the upper portion of thesealing layer 29 a and the self-light-emitting organic material 29 b byan adhesive agent or the like. As the intermediate layer film 29 c, theinsulated and transparent polyimide based film member also is used. Thebase panel 29 d is arranged on the upper portion of the intermediatelayer film 29 c. As the base panel 29 d, a transparent film member or aglass member is used.

The electrode pattern 29 e which is used concurrently by thetouch-sensitive sheet member 180 and the display unit 29 is arranged onthe bottom surface side of the base panel 29 d. The electrode pattern 29e is composed of an ITO film, and a single pattern, a divided pattern inblocks or a divided pattern in a matrix shape is available therefor.

The above-mentioned wiring pattern group 57 is connected to the drivingpower supply 55A, which is not shown in FIGS. 38 and 39, together withthe electrode pattern 29 e of the display unit 29. The driving powersupply 55A applies the DC driving voltage between the electrodes 52 andthe electrode pattern 29 e of the organic EL display device for everyindividual operation key. At that time, it is also allowed to apply theDC driving voltage by changing the voltage-level thereof variably. Thisenables the input device 800 to be configured.

FIGS. 40A to 40C show multiplex examples of display data and shapepresentation signals in the input device 800.

A data format DF1 shown in FIG. 40A is used in a case in which thedisplay of the icon image in the display unit 29 and the sense of touchrepresentation by the electrically conductive rubber 182 in thetouch-sensitive sheet member 180 are functioned simultaneously. Thedisplay data D1, D2, D3 and the shape presentation signals S1a, S2a, S3. . . are packetized and applied alternately between the electrodepattern 29 e and the wiring pattern group 57. The minimum drivingfrequency fm of one packet is around 100 Hz to 1 KHz (0.1 to 10 ms inthe period). The display data D1, D2, D3 . . . are digital-analogueconverted and made as an image signal Sv.

For example, between the electrode 52 which is arranged for everyindividual operation key image and the electrode pattern 29 e, there isapplied the shape presentation signal S1a subsequent to the display dataD1; there is applied the shape presentation signal S2a subsequent to thedisplay data D2; there is applied the shape presentation signal S3subsequent to the display data D3; there is applied the shapepresentation signal S4 subsequent to the display data D4; there isapplied the shape presentation signal S5 subsequent to the display dataD5; and there is applied the shape presentation signal S6 subsequent tothe display data D6, by time divisional multiplexing through the wiringpattern group 57.

A data format DF2 shown in FIG. 40B is used in a case in which only thesense of touch representation is functioned by the electricallyconductive rubber 182 in the touch-sensitive sheet member 180. The shapepresentation signals S1a, S2a, S3, S4, S5, S6 . . . and so on arepacketized and applied between the electrode pattern 29 e and the wiringpattern group 57. For example, there is employed an intermittenttransmission system such that the shape presentation signal S1a and thenext shape presentation signal S2a are transmitted with intermitting onevacant packet to the electrode 52 arranged for every individualoperation key image and the electrode pattern 29 e through the wiringpattern group 57. It is needless to say that a redundant transmissionsystem may be employed in which the shape presentation signal S1a isinserted in two packets and transmitted.

A data format DF3 shown in FIG. 40C is used in a case in which only thedisplay of the icon image in the display unit 29 is functioned. Theitems of the display data D1, D2, D3 . . . are packetized and appliedbetween the electrode pattern 29 e and the wiring pattern group 57. Theitems of the display data D1, D2, D3 . . . are digital-analogueconverted and made as the image signal Sv. For example, in theintermittent transmit system, the display data D1 and the next displaydata D2 are sequentially transmitted with intermitting one vacant packetto the electrode 52 arranged corresponding to the individual operationkey image and the electrode pattern 29 e through the wiring patterngroup 57. In the redundant transmission system, the display data D1which is inserted in two packets and the next display data D2 which isinserted in the next two packets are transferred.

In the above-mentioned input device 800, the items of the display dataD1, D2, D3 . . . are outputted to the display unit 29 instead of theimage signal Sv from a signal processing unit, which is not shown, suchas the image-and-audio-processing unit 44 shown in the FIG. 20. Theshape presentation signals S1, S2, 53 . . . are outputted to thetouch-sensitive sheet member 180 instead of the vibration control signalSout2. It is needless to say that the display data D1, D2, D3 . . . maybe supplied to the display unit 29 from the image-and-audio-processingunit 44 or the shape presentation signals S1′, S2′, S3 . . . may beoutputted to the touch-sensitive sheet member 180.

The following will describe an operation example of the input device800. A selection example of a sense of touch and/or a display functionwill be explained. FIG. 41 shows the selection example of the sense oftouch and/or the display function in the input device 800.

In this example, there is cited a case in which, based on the selectionof a display output application or a shape presentation application ofthe icon images, the input device 800 mounted with the touch-sensitivesheet member 180 displays the operation screen and, by linking with thisdisplay, the sense-of-touch-representing unit is built by applying thedriving voltage to the electrically conductive rubber 182 in thetouch-sensitive sheet member 180 through the electrode 52 and theelectrode pattern 29 e. In this example, when there is an applicationexecution instruction, a case is illustrated in which a selectioncandidate is changed over in order of the display output application theshape presentation application.

In this example, the input device 800 is connected with the control unit15 shown in FIG. 20, in which the CPU 32 thereof controls the drivingpower supply 55A, which is not shown, so as to apply the driving voltagethrough the plurality of electrodes 52 and the electrode pattern 29 e ofthe touch-sensitive sheet member 180 corresponding to the video contentsdisplayed on the display unit 29, and the electrically conductive rubber182 forms the convex and concave shapes at predetermined positionscorresponding to the video contents.

By setting these as the selection condition of the sense of touch and/orthe display function, the CPU 32 inputs an application executioninstruction at step ST81 of the flowchart shown in FIG. 41. Theapplication execution instruction is given to the CPU 32, for example,by making power switch-ON information as a trigger. Thereafter, theprocess shifts to step ST82 where the CPU 32 branches the controlthereof depending on whether the application execution instruction is anexecution instruction of the display output application or otherapplication execution instruction.

If the application execution instruction is an execution instruction ofthe display output application accompanied with the shape presentationapplication or only the display output application instruction, theprocess shifts to step ST83 where the CPU 32 reads the controlinformation of the display output application. The control informationis made correspondence with the display output application, the shapepresentation application or the like beforehand. The CPU 32 controls theoutput(s) of the display unit 29 and/or the touch-sensitive sheet member180 based on the control information.

In this example, because there is assumed a case in which even if theapplication execution instruction is an execution instruction of thedisplay output application, the shape presentation application is alsoexecuted in parallel, the CPU 32 branches the control thereof dependingon the contents of the application execution instruction even in stepST83. If accompanying with the execution of the shape presentationapplication, the process shifts to step ST84 where the CPU 32 controlsthe display unit 29 and the touch-sensitive sheet member 180 so as tofunction the display of the icon images for the operation keys and thesense of touch representation by the electrically conductive rubber 182simultaneously.

For example, the CPU 32 outputs the display data and the shapepresentation signals D1, S1, D2, S2, D3, S3, D4, S4, D5, S5, D6, . . .and so on to the input device 800 by the data format DF1 shown in FIG.40A. The display data D1, D2, D3, . . . and so on and the shapepresentation signals S1′, S2′, S3, . . . and so on are packetized andapplied between the electrode pattern 29 e and the wiring pattern group57 alternately. The items of the display data D1, D2, D3 . . . and so onare respectively digital-analogue-converted and made as an image signalSv. The display unit 29 displays the icon images for the operation keysbased on the image signal Sv. The driving power supply 55A, which is notshown, applies the driving voltage to any of the plurality of electrodes52 and the electrode pattern 29 e of the touch-sensitive sheet member180 at the positions thereof corresponding to the display contents ofthe icon images for the operation keys. Thus, it is constituted suchthat the electrically conductive rubber 182 forms the convex and concaveshapes at predetermined positions corresponding to the image contents.Thereafter, the process shifts to step ST88.

At the above-mentioned step ST83, if the application executioninstruction is an execution instruction of only the display outputapplication, the process shifts to step ST85 where the CPU 32 controlsthe display unit 29 so as to function only the display of the iconimages for the operation keys. For example, the CPU 32 outputs thedisplay data D1, D2, D3, D4, D5, D6 . . . to the input device 800 by thedata format DF3 shown in FIG. 40C. The items of the display data D1, D2,D3 . . . are applied between the electrode pattern 29 e and the wiringpattern group 57 by using the every other packet or the two packets. Theitems of the display data D1, D2, D3 . . . are respectivelydigital-analogue-converted and made as an image signal Sv. The displayunit 29 displays the icon images for the operation keys based on theimage signal Sv. Thereafter, the process shifts to the step ST88.

Also, at the above-mentioned step ST82, if the application executioninstruction is an execution instruction of an application other than thedisplay output application, the process shifts to step ST86 where thecontrol is branched depending on whether the application executioninstruction is an execution instruction of the shape presentationapplication or an execution instruction of the other application. If theapplication execution instruction is an execution instruction of theshape presentation application, the process shifts to step ST87 wherethe CPU 32 reads the control information of the shape presentationapplication. The CPU 32 controls the driving power supply 55A, which isnot shown, based on the control information, thus applying the drivingvoltage to the plurality of electrodes 52 and the electrode pattern 29 eof the touch-sensitive sheet member 180. This enables the electricallyconductive rubber 182 to form the convex and concave shapes atpredetermined positions. Thereafter, the process shifts to the stepST88.

In the step ST88 to which the process shifts, the end of the inputprocessing in the input device 800 is judged. For example, the CPU 32detects the end-instruction outputted from a high rank control system.If the end-instruction is not detected, the process returns to the stepST81 where the above-mentioned processing is repeated. If theend-instruction is detected, the input processing in the input device800 is ended.

In this manner, the input device 800 as the eighth embodiment isprovided with the display device 129 with the touch-sensitive variablesheet function, which has the embodiment of the touch-sensitive sheetmember 180, so that even if the display surface is observed to be a flatshape, when the icon images or the like displayed on the display unit 29are touched with the finger of the operator and the finger is slid onthe upper portion of the electrically conductive rubber 182 under thedisplay screen, it becomes possible to present the input operationaccompanied with the concave and convex feeling. Thus, it becomespossible to provide the input device 800 with the programmabletouch-sensitive variable sheet function for icon touch.

According to the above-mentioned embodiment, the DC driving voltage isapplied to the electrodes 52 corresponding to the respective operationkeys and the electrode pattern 29 e from the driving power supply 55Awith the voltage-level thereof being changed variably. Such aconfiguration enables the position, which corresponds to the individualoperation key, of the electrically conductive rubber 182 sandwichedbetween the electrode 52 becoming the key element and the electrodepattern 29 e to present the programmable sense of touch which gives theconcave and convex feeling with respect to operator's finger or the likeby the protuberant shape or the cave-in shape of the electricallyconductive rubber 182 in which the amount of swelling of the portion ofthe electrically conductive rubber 182 is adjusted or by the originalshape without conducting electricity.

The following will describe a modification example (No. 1) of thedisplay device in the input device 800. FIG. 42 shows a configuration ofa display device 229 with a touch-sensitive variable sheet function,which is applicable to the input device 800. The display device 229shown in FIG. 42 includes the transparent touch-sensitive sheet member180 constituting the touch-sensitive sheet member and the display unit29 on the touch-sensitive sheet member 180. The electrode pattern 29 eand the wiring pattern group 57 which are concurrently used by thetouch-sensitive sheet member 180 and the display unit 29 are alsoincluded. In this example, as the display unit 29, a liquid crystaldisplay device is used instead of the organic EL device, and a backlight 29 g is provided in the lowest layer. With respect to the othermembers and functions, the members similar to those of the displaydevice 129 are used and the functions similar to those of the displaydevice 129 are included, so that the explanation thereof will beomitted.

In this example, the touch-sensitive sheet member 180 is provided on theback light 29 g shown in FIG. 42. The base film 181 is provided on theback light 29 g, and the electrically conductive rubber 182 and theintermediate layer film 183 are layered on this upper portion. Theelectrically conductive rubber 182 is bonded on the upper portion of thebase film 181 by an adhesive agent or the like. As the electricallyconductive rubber 182, a sheet shaped polymer material (artificialmuscle) having transparency and also electric conductivity is used.

In the bottom surface of the electrically conductive rubber 182, theelectrodes 52 are arranged at the positions each corresponding to theindividual operation key, as shown in FIG. 42. The plurality ofelectrodes 52 are respectively connected to the above-mentioned wiringpattern group 57. The intermediate layer film 183 is bonded on the upperportion of the electrically conductive rubber 182 by an adhesive agentor the like. The display unit 29 which forms the liquid crystal displaydevice is bonded on the upper portion of the intermediate layer film 183by an adhesive agent or the like.

The display unit 29 includes the sealing layer 29 a, the liquid crystalmaterial 29 f, the intermediate layer film 29 c, the base panel 29 d,the electrode pattern 29 e and the back light 29 g. The sealing layer 29a has a frame shape shown in FIG. 38 and is provided on the intermediatelayer film 183, which enables the liquid crystal material 29 f to besealed up.

The intermediate layer film 29 c is bonded on the upper portion of thesealing layer 29 a and the liquid crystal material 29 f by an adhesiveagent or the like. The base panel 29 d is arranged on the upper portionof the intermediate layer film 29 c. The electrode pattern 29 e which isconcurrently used by the touch-sensitive sheet member 180 and thedisplay unit 29 is arranged on the lower surface side of the base panel29 d. The above-mentioned wiring pattern group 57 together with theelectrode pattern 29 e of the display unit 29 is connected to thedriving power supply 55A, not shown, which applies the DC drivingvoltage to the electrode 52 and the electrode pattern 29 e of the liquidcrystal display device for every individual operation key. At that time,the DC driving voltage may be applied with the voltage-level thereofbeing changed. In this manner, the display device 229 that is applicableto the input device 800 is configured.

The display device 229 thus configured having the liquid crystal displaydevice on the touch-sensitive sheet member 180 may present the inputoperation accompanied with the concave and convex feeling when the iconimages or the like displayed on the display unit 29 are touched with theoperator's finger and the finger slides on the upper portion of theelectrically conductive rubber 182 under the display screen, even if thedisplay surface thereof is observed to be a flat shape. Thus, it becomespossible to provide the input device 800 with the programmabletouch-sensitive input sheet for icon touch.

The following will describe a modification example (No. 2) of thedisplay device in the input device 800. FIG. 43 shows a configuration ofa display device 329 with a touch-sensitive variable sheet function,which is applicable to the input device 800. The display device 329shown in FIG. 43 includes the transparent touch-sensitive sheet member180 and the display unit 29 on the touch-sensitive sheet member 180. Theelectrode pattern 29 e, which is concurrently used by thetouch-sensitive sheet member 180 and the display unit 29, and wiringpattern groups 57, 58, which are arranged respectively, are alsoincluded. In this example, as the display unit 29, an organic EL deviceis used instead of a liquid crystal display device.

In this example, the touch-sensitive sheet member 180 includes the basefilm 181 shown in FIG. 43 and layered intermediate layer film 183 andelectrically conductive rubber 182 on the base film 181. Theintermediate layer film 183 may be omitted. The intermediate layer film183 is bonded on the upper portion of the base film 181 by an adhesiveagent or the like and the electrically conductive rubber 182 is bondedon the intermediate layer film 183 by the same agent. As theelectrically conductive rubber 182, a sheet shaped polymer material(artificial muscle) having transparency and electric conductivity isused.

A film portion 184 for wiring is provided on the upper portion of theelectrically conductive rubber 182. As the film portion 184, aninsulated and transparent polyimide based film member is used. Thewiring pattern group 57 for the touch-sensitive variable sheet isprovided on the bottom surface side of the film portion 184 and thewiring pattern group 58 for the organic EL device is provided on thefront surface side thereof. In this example, the electrodes 52 shown inFIG. 43 are arranged at the positions each corresponding to theindividual operation key image on a front surface side of theelectrically conductive rubber 182, and the plurality of electrodes 52are connected to the wiring pattern group 57 respectively.

The display unit 29 having the organic EL device is bonded on the upperportion of the film portion 184 for wiring by an adhesive agent or thelike. The display unit 29 includes the sealing layer 29 a, theself-light-emitting organic material 29 b, the intermediate layer film29 c, the base panel 29 d and the electrode pattern 29 e. The sealinglayer 29 a has a frame shape shown in FIG. 38 and is provided on anintermediate layer film 29 h, which enables the self-light-emittingorganic material 29 b to be sealed up.

The intermediate layer film 29 c is bonded on the upper portion of thesealing layer 29 a and the self-light-emitting organic material 29 b byan adhesive agent or the like. The base panel 29 d is arranged on theupper portion of the intermediate layer film 29 c. The electrode pattern29 e is arranged on the bottom surface side of base panel 29 d and isconcurrently used by the touch-sensitive sheet member 180 and thedisplay unit 29. The wiring pattern group 58 of the bottom surface sideof the intermediate layer film 29 h together with the electrode pattern29 e is used to apply the driving voltage to each pixel of theself-light-emitting organic material 29 b.

The above-mentioned wiring pattern groups 57, 58 together with theelectrode pattern 29 e of the display unit 29 are connected to thedriving power supply 55A, not shown, which applies the DC drivingvoltage to the electrode 52 and the electrode pattern 29 e which isconcurrently used with the organic EL device, for every individualoperation key. At that time, the DC driving voltage may be applied withthe voltage-level thereof being changed. In this manner, the displaydevice 329 that is applicable to the input device 800 is configured.With respect to the other members and functions, the members similar tothose of the display device 129 are used and the functions similar tothose of the display device 129 are included, so that the explanationthereof will be omitted.

The display device 329 thus configured having the organic EL device onthe touch-sensitive sheet member 180 may present the input operationaccompanied with the concave and convex feeling when the icon images orthe like displayed on the display unit 29 are touched with theoperator's finger or the like and the finger slides on the upper portionof the electrically conductive rubber 182 under the display screen ifthe wiring pattern group 58 is provided without concurrently using thewiring pattern group 57, even if the display surface is observed to be aflat shape. Thus, it becomes possible to provide the input device 800with the programmable touch-sensitive input sheet for icon touch.

The following will describe a modification example (No. 3) of thedisplay device in the input device 800. FIG. 44 shows a configuration ofa display device 429 with a touch-sensitive variable sheet function,which is applicable to the input device 800. The display device 429shown in FIG. 44 includes the transparent touch-sensitive sheet member180 and the display unit 29 on the touch-sensitive sheet member 180. Theelectrode pattern 29 e, which is concurrently used by thetouch-sensitive sheet member 180 and the display unit 29, and the wiringpattern groups 57, 58, which are arranged respectively, are alsoincluded. In this example, as the display unit 29, a liquid crystaldisplay device is used instead of an organic EL device.

In this example, the touch-sensitive sheet member 180 includes a basefilm 181 on the upper portion of a back light 29 g shown in FIG. 44 andlayered intermediate layer film 183 and electrically conductive rubber182 on the base film 181. The intermediate layer film 183, the base film181 or the like may be omitted. The intermediate layer film 183 isbonded on the upper portion of the base film 181 by an adhesive agent orthe like and the electrically conductive rubber 182 is bonded on theintermediate layer film 183 by the same agent. As the electricallyconductive rubber 182, a sheet shaped polymer material (artificialmuscle) having transparency and electric conductivity is used.

A film portion 184 for wiring is provided on the upper portion of theelectrically conductive rubber 182. As the film portion 184, aninsulated and transparent polyimide based film member is used. Thewiring pattern group 57 for the touch-sensitive variable sheet isprovided on the bottom surface side of the film portion 184 and thewiring pattern group 58 for liquid crystal display device is provided onthe front surface side thereof. In this example, the electrodes 52 shownin FIG. 44 are arranged at the positions each corresponding to theindividual operation key image on a front surface side of theelectrically conductive rubber 182, and the plurality of electrodes 52are connected to the wiring pattern group 57 respectively.

The display unit 29 having the liquid crystal display device is bondedon the upper portion of the film portion 184 for wiring by an adhesiveagent or the like. The display unit 29 includes the sealing layer 29 a,a liquid crystal material 29 f, the intermediate layer film 29 c, thebase panel 29 d and the electrode pattern 29 e. The sealing layer 29 ahas a frame shape shown in FIG. 38 and is provided on an intermediatelayer film 29 h, which enables the liquid crystal material 29 f to besealed up.

The intermediate layer film 29 c is bonded on the upper portion of thesealing layer 29 a and the liquid crystal material 29 f by an adhesiveagent or the like. The base panel 29 d is arranged on the upper portionof the intermediate layer film 29 c. The electrode pattern 29 e isarranged on the bottom surface side of base panel 29 d and isconcurrently used by the touch-sensitive sheet member 180 and thedisplay unit 29. The wiring pattern group 58 of the bottom surface sideof the intermediate layer film 29 h together with the electrode pattern29 e applies the driving voltage to each pixel of the liquid crystalmaterial 29 f.

The above-mentioned wiring pattern groups 57, 58 together with theelectrode pattern 29 e of the display unit 29 are connected to thedriving power supply 55A, not shown, which applies the DC drivingvoltage to the electrode 52 and the electrode pattern 29 e which isconcurrently used by the liquid crystal display device, for everyindividual operation key. At that time, the DC driving voltage may beapplied with the voltage-level thereof being changed. In this manner,the display device 429 that is applicable to the input device 800 isconfigured. With respect to the other members and functions, the memberssimilar to those of the display device 129 are used and the functionssimilar to those of the display device 129 are included, so that theexplanation thereof will be omitted.

The display device 429 thus configured having the liquid crystal displaydevice on the touch-sensitive sheet member 180 may present the inputoperation accompanied with the concave and convex feeling when the iconimages or the like displayed on the display unit 29 are touched with theoperator's finger and the finger slides on the upper portion of theelectrically conductive rubber 182 under the display screen if thewiring pattern group 58 is provided without concurrently using thewiring pattern group 57, even if the display surface is observed to be aflat shape. Thus, it becomes possible to provide the input device 800with the programmable touch-sensitive input sheet for icon touch.

The following will describe a modification example (No. 4) of thedisplay device in the input device 800. FIG. 45 shows a configuration ofa display device 529 with a touch-sensitive variable sheet function,which is applicable to the input device 800. The display device 529shown in FIG. 45 includes the transparent touch-sensitive sheet member180 and the display unit 29 on the touch-sensitive sheet member 180. Anelectrode pattern 185, which is concurrently used by the touch-sensitivesheet member 180 and the display unit 29, and the wiring pattern groups57, 58, which are arranged respectively, are also included. In thisexample, an organic EL device is used as the display unit 29 instead ofa liquid crystal display device and the touch-sensitive sheet member 180is provided on the upper portion of the display unit 29.

In this example, the display device 529 includes a film portion 29 i forthe organic EL wiring. As the film portion 29 i, an insulated andtransparent polyimide based film member is used. The wiring patterngroup 58 for organic EL device is provided on the surface side of thefilm portion 29 i. The display unit 29 having the organic EL device isbonded on the upper portion of the film portion 29 i by an adhesiveagent or the like. The display unit 29 includes the sealing layer 29 a,the self-light-emitting organic material 29 b, the intermediate layerfilm 29 c and a sealing panel 29 d 1. The sealing layer 29 a has a frameshape shown in FIG. 38 and is provided on the intermediate layer film 29c, which enables the self-light-emitting organic material 29 b to besealed up. The sealing panel 29 d 1 is arranged on the upper portion ofthe sealing layer 29 a and the self-light-emitting organic material 29b. The touch-sensitive sheet member 180 is provided on the upper portionof the sealing panel 29 d 1.

In this example, the touch-sensitive sheet member 180 includes the basefilm 181 shown in FIG. 45, the electrically conductive rubber 182, theelectrode pattern 185 and the base panel 186. The electricallyconductive rubber 182, the electrode pattern 185 and the base panel 186are layered on the base film 181. The wiring pattern group 57 isarranged on the front surface side of the base film 181. Theelectrically conductive rubber 182 is bonded on the upper portion of thebase film 181 by an adhesive agent or the like. As the electricallyconductive rubber 182, a sheet shaped polymer material (artificialmuscle) having transparency and electric conductivity is used.

In this example, the electrodes 52 shown in FIG. 45 are arranged at thepositions each corresponding to the individual operation key image onthe bottom surface side of the electrically conductive rubber 182. Theplurality of electrodes 52 are connected to the wiring pattern group 57,respectively. The electrode pattern 185 is arranged on the upper portionof the electrically conductive rubber 182 and is concurrently used bythe touch-sensitive sheet member 180 and the display unit 29. The basepanel 186 is provided on the upper portion of the electrode pattern 185.The driving voltage is applied to each pixel of the self-light-emittingorganic material 29 b via the wiring pattern group 58 of the bottom sideof the above-mentioned intermediate layer film 29 c and the electrodepattern 185.

The above-mentioned wiring pattern groups 57, 58 together with theelectrode pattern 185 of the display unit 29 are connected to thedriving power supply 55A, not shown, which applies the DC drivingvoltage to the electrode 52 and the electrode pattern 185 which isconcurrently used by the organic EL device, for every individualoperation key. At that time, the DC driving voltage may be applied withthe voltage-level thereof being changed. In this manner, the displaydevice 529 that is applicable to the input device 800 is configured.With respect to the other members and functions, the members similar tothose of the display device 129 are used and the functions similar tothose of the display device 129 are included, so that the explanationthereof will be omitted.

The display device 529 thus configured having the touch-sensitive sheetmember 180 on the display unit 29 may present the input operationaccompanied with the concave and convex feeling when the icon images orthe like displayed on the display unit 29 are touched with theoperator's finger and the finger slides on the upper portion of theelectrically conductive rubber 182 under the display screen if thewiring pattern group 58 is provided without concurrently using thewiring pattern group 57, even if the display surface is observed to be aflat shape. Thus, it becomes possible to provide the input device 800with the programmable touch-sensitive input sheet for icon touch.

The following will describe a modification example (No. 5) of thedisplay device in the input device 800. FIG. 46 shows a configuration ofa display device 629 with a touch-sensitive variable sheet function,which is applicable to the input device 800. The display device 629shown in FIG. 46 includes the display unit 29 and the transparenttouch-sensitive sheet member 180 on the display unit 29. The electrodepattern 29 e, which is concurrently used by the touch-sensitive sheetmember 180 and the display unit 29, and the wiring pattern groups 57,58, which are arranged respectively, are also included. In this example,a liquid crystal display device is used as the display unit 29 insteadof an organic EL device.

In this example, the display unit 29 includes a film portion 29 j forthe liquid crystal wiring on the upper portion of the back light 29 gshown in FIG. 46. As the film portion 29 j, an insulated and transparentpolyimide based film member is used. The wiring pattern group 58 for theliquid crystal display device is provided on a front surface side of thefilm portion 29 j.

The display unit 29 having the liquid crystal display device is bondedon the upper portion of the film portion 29 j for the wiring by anadhesive agent or the like. The display unit 29 includes the sealinglayer 29 a, the intermediate layer film 29 c, the sealing panel 29 d 1and the liquid crystal material 29 f. The sealing layer 29 a has a frameshape shown in FIG. 38 and is provided on the intermediate layer film 29c, which enables the liquid crystal material 29 f to be sealed up. Thesealing panel 29 d 1 is bonded on the upper portion of the sealing layer29 a and the liquid crystal material 29 f by an adhesive agent or thelike. The touch-sensitive sheet member 180 is provided on the upperportion of the sealing panel 29 d 1.

In this example, the touch-sensitive sheet member 180 includes the basefilm 181 shown in FIG. 46, the electrically conductive rubber 182, theelectrode pattern 185 and the base panel 186. The electricallyconductive rubber 182, the electrode pattern 185 and the base panel 186are layered on the base film 181. The wiring pattern group 57 isarranged on the front surface side of the base film 181. Theelectrically conductive rubber 182 is bonded on the upper portion of thebase film 181 by an adhesive agent or the like. As the electricallyconductive rubber 182, a sheet shaped polymer material (artificialmuscle) having transparency and electric conductivity is used.

In this example, the electrodes 52 shown in FIG. 46 are arranged at thepositions each corresponding to the individual operation key image onthe bottom surface side of the electrically conductive rubber 182. Theplurality of electrodes 52 are connected to the wiring pattern group 57,respectively. The electrode pattern 185 is arranged on the upper portionof the electrically conductive rubber 182 and is concurrently used bythe touch-sensitive sheet member 180 and the display unit 29. The basepanel 186 is provided on the upper portion of the electrode pattern 185.The driving voltage is applied to each pixel of the liquid crystalmaterial 29 f via the wiring pattern group 58 of the bottom side of theabove-mentioned intermediate layer film 29 c and the electrode pattern185.

The above-mentioned wiring pattern groups 57, 58 together with theelectrode pattern 185 of the display unit 29 are connected to thedriving power supply 55A, not shown, which applies the DC drivingvoltage to the electrode 52 and the electrode pattern 185 which isconcurrently used by the liquid crystal display device, for everyindividual operation key. At that time, the DC driving voltage may beapplied with the voltage-level thereof being changed. In this manner,the display device 629 that is applicable to the input device 800 isconfigured. With respect to the other members and functions, the memberssimilar to those of the display device 129 are used and the functionssimilar to those of the display device 129 are included, so that theexplanation thereof will be omitted.

The display device 629 thus configured having the touch-sensitive sheetmember 180 on the liquid crystal display device may present the inputoperation accompanied with the concave and convex feeling when the iconimages or the like displayed on the display unit 29 are touched with theoperator's finger and the finger slides on the upper portion of theelectrically conductive rubber 182 under the display screen if thewiring pattern group 58 is provided without concurrently using thewiring pattern group 57, even if the display surface is observed to be aflat shape. Thus, it becomes possible to provide the input device 800with the programmable touch-sensitive input sheet for icon touch.

Embodiment 9

FIG. 47 shows a configuration of an input device 900 as a ninthembodiment. In this embodiment, the slide position and the pressingforce of the operator's finger 30 a or the like are detected by readinga pressing force change of the element muscle portion 54 (electricallyconductive rubber 182) in the display device 129, which is differentfrom a case where, as explained in the eighth embodiment, the inputdetection unit 45 is provided between the film portion 5 of the highestlayer and the display device 129 with touch-sensitive variable sheetfunction.

The input device 900 shown in FIG. 47 includes a touch-sensitivevariable sheet unit 190, a load resistance RL, a comparison circuit 450and a driving power supply 505 in a constitution example in which aportion corresponding to one operation key element is extracted.

The touch-sensitive variable sheet unit 190 has the electrodes 51, 52and the element muscle portion 54 (it is also allowed to employ theelectrically conductive rubber 182). Also in this embodiment, theelement muscle portion 54 corresponding to the operation key element aresandwiched between the electrodes 51 and 52. The electrode 51 isconnected, for example, to a ground line GND and the electrode 52 isconnected to the driving power supply 505 through the load resistanceRL.

A connection point of the load resistance RL and the electrode 52 isconnected with the comparison circuit 450 also constituting thedetection unit, which detects the pressing force of the operation bodyby reading the pressing force change (displacement) of the elementmuscle portion 54. In this embodiment, a voltage drop (hereinafter,referred to as output voltage V0) corresponding to the pressing force Fwhich is given to the element muscle portion 54 occurs in the loadresistance RL. For the comparison circuit 450, two comparators 451, 452are used. The respective comparators 451, 452 are connected to a powersupply line VCC and the ground line GND. The connection point of theload resistance RL and the electrode 52 is connected to plus (+)terminals of the respective comparators 451, 452.

Minus (−) terminals of the comparators 451, 452 of each stage of thecomparison circuit 450 are connected to the driving power supply 505,and a reference voltage VREF is applied to the minus (−) terminals ofthe comparators 451, 452. The comparator 451 for position detection issupplied with a threshold voltage Vth1 for position detection as thevoltage VREF and the comparator 452 for pressing force judgmentthreshold is supplied with a threshold voltage Vth2 for pressing forcejudgment. The driving power supply 505 is connected to the power supplyline VCC and the ground line GND. The threshold voltages Vth1, Vth2 andthe driving voltage Vo are set by the instruction data D from the CPU32. The comparator 451 compares the threshold voltage Vth1 with theoutput voltage V0 and outputs a position detection signal Si to the CPU32 when the output voltage V0 which exceeds the threshold voltage Vth1is obtained. The comparator 452 compares the threshold voltage Vth2 withthe output voltage V0 and outputs a press detection signal S2 to the CPU32 when the output voltage V0 which exceeds the threshold voltage Vth2is obtained.

The following will describe an input processing example of the inputdevice 900. FIGS. 48 and 49 show an operation example (Nos. 1, 2) of oneoperation key element. FIG. 50 shows the input processing examplethereof.

In this embodiment, the driving power supply 505 applies the drivingvoltage Vo of the voltage-level between the electrode 51 and theelectrode 52 based on the instruction data D of the shape presentationwhich is inputted from the CPU 32. There is cited a case in which thethreshold voltage Vth1 is set in the comparator 451 and the thresholdvoltage Vth2 is set in the comparator 452.

By setting these as the input condition, at step ST91 of the flowchartshown in FIG. 50, the position detection signal S1 and the pressdetection signal S2 are inputted to an A/D driver 31. According to thetouch-sensitive variable sheet unit 190 shown in FIG. 48, the shape ofthe element muscle portion 54 is changed to a convex shape at a time ofthe shape presentation. This shape change is based on a fact that theelement muscle portion 54 changes the shape thereof to the convex shapeby inputting the instruction data D of the shape presentation to thedriving power supply 505 from the CPU 32 and by applying the drivingvoltage Vo of the voltage-level based on the instruction data D to theelectrode 51 and the electrode 52. In this state, the comparator 451does not detect the output voltage V0 exceeding the threshold voltageVth1, so that the position detection signal S1 is a low level=0. Also,the comparator 452 also does not detect the output voltage V0 exceedingthe threshold voltage Vth2, so that the press detection signal S2 isalso a low level=0.

Then, the position detection in step ST92 and the press detection instep ST95 are processed in parallel. According to the touch-sensitivevariable sheet unit 190 shown in FIG. 49, the shape of the elementmuscle portion 54 is changed to the concave shape at a time of the shapepresentation by pressing the element muscle portion 54 with theoperator's finger 30 a or the like. The operator's finger 30 a or thelike presses the element muscle portion 54, so that the electric current“i” flowing in the load resistance RL changes. For example, the electriccurrent decreases or increases as compared with the electric current “i”of a state in which there is no press on the element muscle portion 54.The change of this electric current “i” appears as the voltage dropbetween both terminals of the load resistance RL.

According to the position detection processing in the step ST92, theslide position of the operator's finger 30 a or the like is detected bymonitoring the output voltage V0 of the connection point of the loadresistance RL and electrode 52. In this embodiment, at step ST93, thecomparator 451 compares the threshold voltage Vth1 with the outputvoltage V0 and monitors the output voltage V0 exceeding thresholdvoltage Vth1. At this time, when the comparator 451 detects outputvoltage V0 exceeding the threshold voltage Vth1, for example, theposition detection signal S1 of a high level=1 (it is also allowed to bethe position detection voltage V1) is outputted to the A/D driver 31.The A/D DRIVER 31 outputs the position detection information D1, inwhich the position detection signal S1 is analogue-digital-converted, tothe CPU 32. When the output voltage V0 exceeding such a thresholdvoltage Vth1 is detected, the process shifts to step ST94 where theposition detection information D1 is stored in the memory unit 35 asshown in FIG. 20.

According to the press detection processing which executes in the stepST95 in parallel with the above-mentioned processing, the pressing forceof the operator's finger 30 a or the like is detected by monitoring theoutput voltage V0 of the connection point of the load resistance RL andthe electrode 52. In this embodiment, at step ST96, the comparator 452compares the threshold voltage Vth2 with the output voltage V0 andmonitors the output voltage V0 exceeding the threshold voltage Vth2. Atthis time, when there is a further strong press on the element muscleportion 54, the comparator 452 detects the output voltage V0 exceedingthe threshold voltage Vth2, so that, for example, the press detectionsignal S2 of a high level=1 (it is also allowed to be the positiondetection voltage V2) is outputted to the A/D DRIVER 31. The positiondetection voltage V1 and the press detection voltage V2 are thedifferent in the voltage-level (V1≠V2). The A/D driver 31 outputs theposition detection information D2, in which the position detectionsignal S2 is analogue-digital-converted, to the CPU 32.

In the above-mentioned embodiment, when the output voltage V0 exceedingthe threshold voltage Vth2 is detected, the process shifts to step ST97where the input is determined by making the press detection informationD2 as a trigger. Thus, in the CPU 32, it becomes possible to detect theslide position and pressing force F of the operator's finger 30 a or thelike from the position detection information D1 and the press detectioninformation D2.

In this manner, the input device 900 as the ninth embodiment is providedwith the touch-sensitive variable sheet unit 190, the load resistance RLand the comparison circuit 450 with respect to the one operation keyelement, and the output voltage V0 of the connection point of theelectrode 52 and the load resistance RL of the touch-sensitive variablesheet unit 190 is monitored by the comparison circuit 450. When, forexample, the twenty operation keys exist, it is enough if the twentycircuits each for monitoring the above-mentioned output voltage V0 areprovided.

Consequently, it is possible to build the function of the inputdetection unit 45 by the element muscle portion 54 (electricallyconductive rubber 182) and the comparison circuit 450 of thetouch-sensitive variable sheet unit 190, thereby enabling to be omittedthe resistive touch panel or the capacitive touch panel whichconstitutes the input detection unit 45 in the fifth to eighthembodiments. The comparison circuit 450 is not necessary to be arrangedon the display screen and can be arranged on a circuit board apart fromthe display screen, so that it becomes possible to improve the designrestriction of the input detection unit 45.

Moreover, it is possible to execute the convex and concave shaperepresentation through the sense of touch on the display screen ascompared with the past system. Further, it is possible to change therepresentation place thereof depending on the state of the applicationof the operation key screen, so that the user can obtain the sense oftouch information (simple concavity and convexity or skin touch ofcloth) which is obtained by touching the key board of the past or thematerial having the convex and concave shape of the existent world fromthe operation plane. Further, it becomes possible to improve theoperability incredibly.

Embodiment 10

FIGS. 51A to 51C show a configuration of a mobile phone 110 as a tenthembodiment.

The mobile phone 110 shown in FIG. 51A is provided with a nonskid sheet160A to which the touch-sensitive sheet member 160 explained in thesixth embodiment is applied. The nonskid sheet 160A is provided so as tosurround the side surface region that the operator grasps in the mobilephone 110, for example.

The mobile phone 110 shown in FIG. 51B has a housing 111, and forexample, the electrode 52, the muscular sheet portion 54A and theelectrode 51 are layered so as to surround this housing 111. Withreference to the driving example shown in FIG. 35, this is a case (OFF)in which there is no the shape presentation instruction for executingthe shape presentation from the high ranking CPU 32 to the driving powersupply 55A. In this case, the change of the convex and concave shape isnot seen in a periphery of the side surface of the housing 111. There isno difference from the state of a periphery of the side surface of themobile phone of the past system.

The mobile phone 110 shown in FIG. 51C indicates a case (ON) where thereis the shape presentation instruction for executing the shapepresentation from the high ranking CPU 32 to the driving power supply55A. In this case, the convex and concave shape appears in the peripheryof the side surface of housing 111. In this case, the side surfaceportion of the housing of the mobile phone 110 on which the operatorgrasps changes to the waveform-like or the convex and concave shapes.With respect to the control for changing only the grasping portion tothe convex and concave shape, it may employ the control method explainedin the ninth embodiment. Thus, a grip feeling come to be given ascompared with the state of the periphery of the side surface of themobile phone of the past system.

Embodiment 11

FIGS. 52A to 52C show a configuration of a variable sheet device 220 forbraille as an eleventh embodiment. The variable sheet device 220 forbraille shown in FIG. 52A is provided with a variable sheet 180A forbraille to which the touch-sensitive sheet member 180 explained in theeighth embodiment is applied. The variable sheet 180A for braille isprovided, for example, on the operation screen which the operatortouches in the variable sheet device 220 for braille. In FIG. 52A,cylinder shapes shown with the broken lines form braille elements, andare portions in which the muscular sheet portion 54A raise in the convexshape by reflecting the shape of each of the circular shaped electrodes51 which is not shown.

The variable sheet device 220 for braille shown in FIG. 52B includes thedisplay unit 29 and layered input detection unit 45 and variable sheet180A for braille in this order on the display unit 29. For example, thevariable sheet 180A for braille includes the base film 181 having thewiring pattern group 57, the muscular sheet portion 54A bonded on thisbase film 181, the electrode 51 provided on the rear surface side ofthis muscular sheet portion 54A and the base panel 186 on the electrode51, which are layered. It should be noted that the display unit 29 andthe input detection unit 45 may be omitted.

Also in this embodiment, with reference to the driving example shown inFIG. 35, the shape presentation instruction for executing the shapepresentation of the braille element is supplied to the driving powersupply 55A from the high rank CPU 32. This is a case (OFF) in whichthere is no the shape presentation instruction. In this case, the changeof the convex and concave shape is not seen on the operation screenwhich the operator touches by his or her finger or the like.

The braille variable sheet device 220 shown in FIG. 52C indicates a case(ON) in which there is the shape presentation instruction from the highrank CPU 32 to the driving power supply 55A. In this case, the convexand concave shape appears on the operation screen which the operatortouches. In this case, a side surface portion of a housing of thevariable sheet device 220 for braille which the operator touches changesto the cylindrical protrusive (convex) shape. With respect to thebraille appearance control for changing the convex portion constitutingthe braille block to the convex shape, it may employ the control methodexplained in the ninth embodiment. Thus, it becomes possible to providethe braille-talkable variable sheet device 220 for braille in which thebraille block changes and appears based on the control information ascompared with a fixation type braille block of the past system.

Although, in the above-mentioned first to eleventh embodiments, thetouch-sensitive sheet members having the individual functionrespectively have been described, they are not limited to those; anycombination of the touch-sensitive sheet members having the individualfunction respectively may be used. For example, there may be used acombination of the first touch-sensitive sheet member in which thesense-of-touch-representing unit forms the apertures p1 to p25 forpresenting a sense of touch each having a predetermined size aperturediameter and being perforated at a predetermined position in the basemember 1 and the medium-supplying unit has the air-circulation unit 3for sending air to the apertures p1 to p25 or for taking in air from theaperture p1 to p25; the second touch-sensitive sheet member in which thesense-of-touch-representing unit forms bag portions q1 to q25 forpresenting a sense of touch each having a predetermined size and beingarranged at a predetermined position of the base member 11 and themedium-supplying unit has the ventilation unit for sending air to thebag portions q1 to q25; and the third touch-sensitive sheet member inwhich the sense-of-touch-representing unit includes the electricconductive element bag portions E1 to E25, the electrically conductiverubber 82 or the like for presenting a sense of touch each having apredetermined sized electrodes 51, 52 and being arranged at apredetermined position of the insulated and transparent member and themedium-supplying unit has the driving power supply 55A for supplying thedriving voltage Vo to the electrodes 51, 52 of the element bag portionsE1 to E25, the electrically conductive rubber 182 or the like.

The present application is preferably applied to an electronic apparatusof a digital camera, a video camera, a mobile phone, a mobile terminaldevice, a desk-top type PC, a note type PC, a braille block device, anautomatic teller machine or the like including a touch-sensitive inputfunction for presenting a sense of touch when touching an icon screenwith the operator's finger or the like.

It should be understood by those skilled in the art that variousmodifications, combinations, sub-combinations and alterations may occurdepending on design requirements and other factors insofar as they arewithin the scope of the appended claims or the equivalents thereof.

It should be understood that various changes and modifications to thepresently preferred embodiments described herein will be apparent tothose skilled in the art. Such changes and modifications can be madewithout departing from the spirit and scope of the present subjectmatter and without diminishing its intended advantages. It is thereforeintended that such changes and modifications be covered by the appendedclaims.

The invention is claimed as follows:
 1. A touch-sensitive membercomprising: a body having a sheet shape; a sense-of-touch-representingunit formed on the body and including a plurality of sensing elements;and a medium-supplying unit connected to the body and configured tosupply a medium to and from the different sensing elements therebyenabling a change in shape of the sensing elements based on a volumechange of the medium contained within the sense-of-touch representingunit.
 2. The touch-sensitive member according to claim 1, wherein themedium-supplying unit includes a pressure generator that changes thepressure of the medium inside the sense-of-touch representing unit. 3.The touch-sensitive member according to claim 2, wherein the pressuregenerator includes a programmable function that individually changes thevolume of the medium contained within each of the sensing elements. 4.The touch-sensitive member according to claim 2, wherein the pressuregenerator includes a piezoelectric device.
 5. The touch-sensitive memberaccording to claim 1, wherein each sensing element includes a pluralityof bag portions.
 6. The touch-sensitive member according to claim 1,wherein the body includes a flow channel fluidly connecting themedium-supplying unit to the sensing elements.
 7. An input apparatuscomprising: a touch-sensitive member including a body having a sheetshape, a sense-of-touch-representing unit formed on the body andincluding a plurality of sensing elements, and a medium-supplying unitconnected to the body and configured to supply a medium to and from thedifferent sensing elements thereby enabling a change in shape of thesensing elements based on a volume change of the medium contained withinthe sense-of-touch representing unit; a display unit; and a processorcontrolling the medium-supply unit to change the shape of the sensingelements corresponding to image contents displayed on the display unit.